DoD SBIR FY01.1 - SOLICITATION SELECTIONS w/ ABSTRACTS

DoD SBIR FY01.1 - SOLICITATION SELECTIONS w/ ABSTRACTS
Navy - Air Force - DARPA - BMDO - DTRA - SOCOM - CBD - NIMA

---------- NAVY ----------

209 Phase I Selections from the 01.1 Solicitation

(In Topic Number Order)

APPLIED MATERIAL TECHNOLOGIES, INC. 2302 S. Fairview Street Santa Ana, CA 92704
Phone: PI: Topic#:	(714) 545-8825 Mr. William E. Davis NAVY 01-001 Selected for Award
Title:	Advanced Packaging Technology for Trident Missile Systems
Abstract:	This SBIR proposal is for the development of innovative packaging of radiation hardened electronics in support of Strategic Missile Guidance System upgrades for sea launched ballistic missiles (SLBMs). The Navy Strategic Systems Programs has authorized Life extensions for the Trident Fleet Ballistic Missile Submarines Hull and Missile systems and hence there is significant interest in utilizing all advancements in technology that are available. The Navy has authorized a 20 year extension to the life of the Trident System providing a total life of 42 years; all of the vehicles will be armed with the Trident II D5 missiles. During the life of the Trident missile system the electronics are active and utilized. It is desirable to continue to upgrade the electronics with the latest technology especially technologies that improve radiation hardness. The inertial guidance electronics will be the focus for this project. The opportunity for this SBIR project will be to develop packaging technologies that can be integrated and transferred to the Trident II submarine system throughout the current and extended life of the system. AMT and it's partner Raytheon will develop and apply new technologies that include ball grid array and column grid array interconnection and plastic encapsulated microcircuits.Military systems are rapidly faced with obsolescence and parts availability issues, especially for microelectronic devices. This project will provide an opportunity to utilize commercial technologies that are widely available from large suppliers of semiconductors and significantly enhance the options for the Navy. AMT is presently developing procedures and systems for certifying commercial products for military use and this project will have direct relevance to on-going activities that will lead to high reliability electronics for military applications.

MATERIALS & ELECTROCHEMICAL RESEARCH 7960 S. Kolb Rd. Tucson, AZ 85706
Phone: PI: Topic#:	(520) 574-1980 Dr. J.C. Withers NAVY 01-002 Selected for Award
Title:	Ceramic Composite Lined Metal Composite Gun Barrels for Small Arms
Abstract:	Rapid fire small arms gun performance is limited by wear and erosion in the chromium plated steel gun barrels which are also heavy for infantry use. Ceramic lined steel gun barrels have demonstrated potential to eliminate the wear and erosion but have failure from cracking for lack of toughness, uniform triaxial restraint and offer negligible weight savings. Recent developments in ceramic matrix composites (CMCs) have the potential to overcome the toughness and cracking limitations of monolithic ceramics. CMC liners coupled with outer shells of metal matrix composites (MMCs) have the potential to eliminate wear and erosion, and achieve up to 50% weight savings over chromium plated steel barrels. This program will demonstrate the fabrication of very high thermal conductivity and toughness CMCs that are functionally graded into MMCs to produce a small arms rapid fire barrel which eliminates wear and erosion, and provides 50% weight savings. Modeling and simulation will be conducted concurrent with CMC composition and fabrication processing demonstration, and screen tested using vented bomb, barrel burst test and thermal conductivity. Selected processing will be utilized to fabricate select CMC composition(s) into barrels including attachments, which will be live fire tested.Ceramic composite lined metal composite tubes not only have a substantial market for all gun barrel applications in DoD, law enforcement and recreational, but such composites have a plethora of applications in engines, brakes and chemical processing industries.

SURFACE TREATMENT TECHNOLOGIES, INC. P.O. Box 1027 Glen Burnie, MD 21060
Phone: PI: Topic#:	(410) 332-0633 Mrs. . Amy Harmon Krtanjek NAVY 01-002 Selected for Award
Title:	Ceramic Barrels for Small Arms
Abstract:	Surface Treatment Technologies, Inc. (ST2) proposes the development of Electro-Spark Alloying (ESA) technology for the formation of ceramic coatings on current gun barrel steel and lightweight alternative barrel materials, such as titanium. ESA technology involves the arc deposition of metal and ceramic coatings directly onto metal surfaces. The process forms a coating with a full metallurgical bond, forms no heat affected zone in the base alloy, creates a coating that is amorphous to nano-grained in structure, and exhibits wear and erosion properties far superior to conventional coatings of ceramics and composites of similar chemistries. In addition, the process permits the investigation of functionally gradient coatings for the end-use application. In the Phase I effort, ST2 will investigate both ceramic and refractory metal candidate coatings for conventional gun steel and titanium barrel materials. Unique to this approach will be the coating of a barrel blank, followed by a rotary forging process that will maintain the structural integrity of the coating. This evaluation will include full mechanical and metallurgical analyses, as well as live-fire testing of rifled barrel components. Phase II will expand the potential coatings candidate options, and then focus on manufacturing scale-up requirements in anticipation of a Phase III transition. Lightweight gun barrels with extended life, yet using no toxic and hazardous plating materials for military, law enforcement, and commercial applications. Additional benefits will focus on the power tool industry, medical tools and implants, and engine/transmission markets.

THOR TECHNOLOGIES, INC. 7600 Jefferson NE, Suite 9-115 Albuquerque, NM 87109
Phone: PI: Topic#:	(505) 296-3615 Dr. Stuart T. Schwab NAVY 01-002 Selected for Award
Title:	Advanced Ceramic Barrel Materials & Processing Methods
Abstract:	Barrel erosion, which is produced by the combination of high temperature and pressure with aggressive propellant combustion products, and the action of the projectile, results in decreased muzzle velocities, increased projectile yaw, and decreased accuracy. New material designs are needed to mitigate erosion in gun barrels, which limits service life Ceramic composites are a leading material candidate for gun barrels because of their thermochemical stability, erosion resistance and low density. Ceramic composites can prolong service life and provide other enhancements to gun barrels. New designs and manufacturing methods are needed to integrate ceramic composite barrels with current infantry weapons, such as the M249 Squad Automatic Weapon. Thor Technologies, Inc. will team with Los Alamos National Laboratory, Materials Research & Design, and FN Manufacturing, Inc. (FNMI) to develop a novel hybrid ceramic composite design and an innovative, low-cost manufacturing method. Polymer infiltration/microwave pyrolysis processing enables manufacture of ceramic composites with integral metallic attachments. In Phase I, a prototype hybrid ceramic barrel will be produced and used to demonstrate improved service life through firing tests at FNMI. The Principal Investigator and the project team have the experience and expertise to develop ceramic composite gun barrels suitable for the infantry combat environment Enhancement of barrel service life will reduce weapon lifecycle costs. The availability of low cost ceramic composites will benefit aerospace and industrial applications ranging from jet engines and rocket motors to corrosion-proof piping for chemical processing.

COHERENT TECHNOLOGIES, INC. 655 Aspen Ridge Drive Lafayette, CO 80026
Phone: PI: Topic#:	(303) 604-2000 Dr. John Marquardt NAVY 01-003 Selected for Award
Title:	Nonlinear Optical Up-Converter for Eye-Safe Imaging
Abstract:	Active imaging in the short- and mid-wave infrared has well-known benefits versus shorter wavelengths: eye safety, better visibility through battlefield obscurants, high atmospheric trans-mission, and reduced background emission. However, there are no suitable imaging detectors at eye-safe wavelengths. CTI proposes a nonlinear sum-frequency generator (SFG) to convert an image at 1.55 mm to a shorter wavelength where image intensifiers can be used. In addition, the SFG can provide spectral filtering and optical range-gating capability. Modern nonlinear optical materials can operate with high efficiency using modest pump sources in a compact design. CTI proposes a SFG converter with a large field-of-view, that is relatively temperature insensitive, and operates at room temperature. In Phase I, CTI will conduct detailed analyses and laboratory demonstrations to validate the proposed nonlinear up-converter. In Phase II, an imaging breadboard converter will be tested, optimized, and delivered.(1) increase detection sensitivity in eye-safe laser radar imaging, (2) demonstrate enhanced 2D LADAR imaging through SFG converter, (3) demonstrate receiver techniques through optical range-gating.

METROLASER, INC. 18010 Skypark Circle, Suite 100 Irvine, CA 92614
Phone: PI: Topic#:	(949) 553-0688 Dr. Vladimir Markov NAVY 01-003 Selected for Award
Title:	Eye-safe LADAR Laser Transmitter
Abstract:	This Small Business Innovation Research Phase I Project will produce a design for a monoblock configuration pulsed Er-Yb:glass micro-laser at 1540 nm, suitable for use in coastal LADAR applications at ranges greater than 1 km. Beside LADAR such a laser would be an extremely useful tool for a number of important applications; range finding, remote sensing, optical communications, etc. Our preliminary analysis indicates that the best way to meet the requirements for this laser is through an approach based on the optimal selection of pumping wavelength and cavity configuration, where both pumping and oscillation resonators form attached cavities. This method allows for scalability and versatility, while still achieving excellent performance in a relatively simple and rugged monoblock configuration.The developed system will radically improve the characteristics of lasers at 1540 nm, bringing its construction to a monoblock micro-design. In the commercial sector, the proposed laser will serve as an ideal source for parametric oscillators, high data transfer rate communication systems, spectroscopy, clocks, etc.

ARMORWORKS, INC. 2495 S. Industrial Park Ave Tempe, AZ 85282
Phone: PI: Topic#:	(480) 517-1150 Mr. William J. Perciballi NAVY 01-004 Selected for Award
Title:	AAAV Composite Armor Systems
Abstract:	This proposal describes and SBIR Phase I program to develop a high-performance, low-cost composite armor for the AAAV. Ballistic protection offered by state-of-the-art composite materials are presented and compared to demonstrate the need and performance goals for composite materials as fragment armors and as backings in ceramic armor systems. Ballistic performance models are presented and compared. Hybrid composite armor designs that use low-cost materials are discussed along with development and test plans. Cost models for composite armors are presented. Flammability testing proposed for candidate AAAV armor systems is outlined.Improved composite armor technology applicable to bullet and fragment armor systems. Improved ceramic armor designs that reduce cost and imrpove multiple impact protection of ceramic armors against armor piercing bullets. Composite armor designs and ballistic performance models applicable to personnel, aircraft, ship, and ground vehicle armor systems.

COMPOSIX CO. 120 O'Neill Drive Hebron, OH 43025
Phone: PI: Topic#:	(740) 929-4200 Mr. DONALD L. BLAKE NAVY 01-004 Selected for Award
Title:	High Performance Composite Backing Armor System for the Advance Amphibious Assault Vehicle (AAAV)
Abstract:	The AAAV requires lightweight components that can be affordably produced and assembled. The goal of this SBIR is to develop an effective armor system that can use low cost materials while minimizing overall weight. Reduction in fabrication and material cost of the armor solution translates into a meaningful reduction in the vehicle cost. In this SBIR, we expand the state of the art through the use of conventional materials in innovative ways. The technology focuses of on ways to reduce the overall installed armor costs through material, and manufacturing innovations.We expect that the technology developed in this SBIR will be immediately applicable to other application areas such as Navy patrol boats, Army spall liners, and aircraft armor, where weight and cost are important. Additionaly, we belieive that we can modify the material system to allow its use as a flexible body armor material for law enforcement. The law enforcement market is very price sensitive, and many of the materials in use today are very cost prohibitive. This material would provide a very attractive alternative.

KAZAK COMPOSITES, INC. 32 Cummings Park Woburn, MA 01801
Phone: PI: Topic#:	(781) 932-5668 Mr. James Gorman NAVY 01-004 Selected for Award
Title:	Multi-Layer Interlocked Pultruded Composite Armor for AAAV
Abstract:	KaZaK Composites Incorporated proposes in this Phase I project to develop a novel composite process allowing low cost fabrication of high performance backing armor for AAAV. Key elements of this process implementation include pultrusion of multi-layered glass and hybrid glass/aramid preforms in which the layers are both differentially infiltrated with resin and interlocked with a through-thickness reinforcement. The type and degree of layer interlocking will be chosen to optimize ballistic performance. The varying density of matrix through the thickness of the composite, and the possibilities of multi-resin layering will also be evaluated to optimize the performance-weight-cost tradeoff. During the Phase I project, 12" panels of different constructions will be fabricated and subjected to ballistic testing to resolve key architecture details. Upon selection of a promising composite architecture, a trial run of continuous pultrusion for that composite will be performed. This trial of a multi-layer/material composite armor will not only shed light on processing, but will also provide specimens for ballistic testing. While we intend to evaluate novel composite architectures, our primary focus in Phase I will be to develop the continuous processing parameters allowing a "good" ballistic composite architecture to be fabricated at the lowest possible cost via pultrusion.KCI anticipates that the results of the proposed project will have widespread application in governmental and commercial arenas, both as a means of fabricating highly effective backing armor for various vehicles, and as a primary armor for those applications having less demanding threats. We believe that concentrating on reducing the cost of "good" architectures is at present more important than wringing out the optimum specific weight performance in order to enhance commercialization to law enforcement and VIP protection markets. Given a low cost processing scheme for the basic multi-layered/multi-material construction, architecture modifications to optimize ballistic performance can be easily implemented, either through material substitution or distribution and orientation.

ACOUSTECH CORP. P. O. Box 139 State College, PA 16804
Phone: PI: Topic#:	(814) 867-2629 Mr. James A. McConnell NAVY 01-005 Selected for Award
Title:	Piezoelectric Single Crystal Applications
Abstract:	A study is proposed in which the performance of an underwater acoustic vector sensor (AVS) containing conventional piezoelectric transducers is compared with that of an AVS containing single crystal piezoelectric transducers. An acoustic vector sensor is a device that measures three orthogonal components of the acoustic particle velocity in conjunction with the acoustic pressure at a single point in space. The sensor employs unimorph bender disks to measure pressure and bimorph bender disks to measure velocity. The size of each device is the same, so the chief parameters that will be evaluated are the sensitivity and bandwidth. Acoustic vector sensors are being planned for use in tactical underwater surveillance platforms that are operated by the U. S. Navy.Improve performance of tactical underwater surveillance platforms operated by the U. S. Navy.

AETHER WIRE & LOCATION, INC. 5950 Lucas Valley Road Nicasio, CA 94946
Phone: PI: Topic#:	(415) 662-2055 Mr. Robert A. Fleming NAVY 01-005 Selected for Award
Title:	Personnel Identification and Location for MOUT Applications
Abstract:	The Marine Corps is currently enhancing its capabilities in Military Operations On Urban Terrain (MOUT) in response to a clear trend toward increased military conflicts in urban settings. The MOUT capability requires new technologies, including a next-generation position-location system that penetrates building walls and tracks individuals within urban structures. This system must be compact, rugged, power-efficient, undetectable by enemy personnel, and immune from multipath and ambient electromagnetic interference. �ther Wire has developed a communication/location system-the Localizer-that represents a system that could be optimized to meet these requirements. This system is based on Ultra-Wideband RF communications; its signals are inherently difficult to jam, have good multipath properties, and can penetrate urban structures. The Localizer represents the current state of the art and is the product of 10 years of internal and Government funded R&D. �ther Wire's world class technical expertise will make it possible to meet/exceed the Marine Corps' requirements for MOUT within the limited scope of this SBIR effort. For Phase I, �ther Wire proposes to 1) address key design issues (e.g., signal attenuation, multipath removal, range limitations, power consumption), 2) construct and test demonstration model, and 3) develop recommendations for further localizer development in Phase II. Phase I success will lead to a Phase II project focused upon advancing the prototype development and optimization/scale-up of the Localizer system for field demonstration. �ther Wire anticipates developing a next-generation Localizer that will provide accurate personnel identification/location capabilities for the Marines' MOUT applications. This location technology also has diverse commercial potential in applications including asset tracking, fireman buddy systems, home navigation systems for the blind, house-arrest monitors, and automobile collision-avoidance systems.

AMERICAN GNC CORP. 888 Easy Street Simi Valley, CA 93065
Phone: PI: Topic#:	(805) 582-0582 Dr. Ching Fang Lin NAVY 01-005 Selected for Award
Title:	Multi Sensor Personnel Identification System
Abstract:	The objective of this SBIR Phase I project is to design, fabricate, and evaluate a low cost, small size and lightweight, Multi Sensor Personnel Identification System, based on AGNC's commercial product with AGNC's worldwide pending patents, the AGNCTM-2000 CMINU/GPS Palm NavigatorTM. The Palm Navigator is based upon the coremicroTM IMU with MEMS inertial sensors. This provides a problem solution that is low power, low cost, small size, and lightweight. In the proposed system, the coremicroTM IMU is combined with an RF data link and an acoustic phased array sensor for underground and inside structures communication. The acoustic sensor, when used in a cooperative network, is utilized for interrogation, and identification of friend or foe. The proposed system is coupled with a build-in state-of-the-art GPS (Global Positioning System) chipset and exploits the GPS signals to calibrate and align the IMU when GPS is available. During those instances when no radio contact is possible, a sonar relay device is provided to furnish continuous radio contact with remote users. The techniques and systems developed in this project provide a combined military/commercial product that can be exploited in various military and commercial applications, such as Urban warfare, law enforcement, fire fighting, and emergency services equipment.

INTELLIGENT AUTOMATION, INC. 7519 Standish Place, Suite 200 Rockville, MD 20855
Phone: PI: Topic#:	(301) 590-3155 Dr. Leonard Haynes NAVY 01-005 Selected for Award
Title:	Time-Modulated Ultra-Wideband Personnel Identification System
Abstract:	Within the last few years low cost ultra-high precision time delays have become available, and these now make it possible to build UWB communication systems which have no carrier frequency. The only signals transmitted are pulses. With current hardware, the pulses are � nanosecond, and a typical duty cycle is 1/500. The energy of these pulses extends approximately from .5 to 4 gigahertz, and the energy content in any conventional frequency band is far below the noise. Friendly forces (cooperative targets) will carry a small TM-UWB radio which will: 1) provide a local area communication net between friendly forces within range; 2) transmit a unique pseudo random code which will provide a private channel and which will also uniquely identify the particular radio, and 3) provide an accurate range measure from the user to any other radio. TM-UWB technology will also assist in tracking non-cooperative targets inside buildings and under ground. This will be done using Synthetic Aperture and/or Phased Array techniques. Our partner company, Time Domain Corporation is already working on a SAR based system to be used by police for tracking motion through walls, and good results have already been demonstrated.A key opportunity for TM-UWB short range wireless networks is the industrial wireless LAN market. In 1997, wired LAN equipment sales for Internet service providers alone was $18B, while wireless LAN equipment sales were a mere $213M - a gap that is beginning to close even as the market scale increases. As an example, in the health care industry TM-UWB offers a single mechanism for wireless communication to and from mobile instruments, plus it offers the ability to track the position of each of those mobile assets. TDC has raised $70 million in private funds, including funds from Sony, Siemens, US West, and Marconi plus many private investors, all of which is being expended in perfecting TM-UWB.

MATERIALS SYSTEMS, INC. 521 Great Road Littleton, MA 01460
Phone: PI: Topic#:	(978) 486-0404 Mr. Daniel Fiore NAVY 01-005 Selected for Award
Title:	High-Output Solid-State-Converted Piezoelectrics for Remote Vehicle Sonars
Abstract:	This program will demonstrate the performance advantages of applying solid-state- converted (SSC) PMN-PT 1-3 composite transduction materials to selected Navy sonar systems which require greater bandwidth, lower frequency operation, and/or higher source levels to meet their operational objectives. The SSC materials are highly oriented piezoceramics which exhibit up to 80% the strain of very expensive piezo-single crystals, at a cost only modestly higher than traditional piezoceramics. In Phase I, MSI will (a) develop transducer concepts consistent with the emerging SSC manufacturing technology, (b)�evaluate the insertion potential into selected Navy sonar systems, (c) down-select to one or more insertion opportunities based on system payoff and transition sponsor interest, and (d) develop and model prototype transducer designs for each of the selected insertion platforms. The follow-on Phase�II program will focus on hardware fabrication and performance demonstration.Utilization of higher strain, higher coupling transduction materials will enable acoustic projector designs which are more compact, have increased bandwidths and lower achievable operating frequencies, and provide higher source levels. Smaller and more sensitive hydrophones will also be realized. Commercial applications include medical imaging, NDE, inkjet printing, high strain actuators, optical switching, automotive engine control, and commercial sonars.

Q PEAK, INC. 135 South Road Bedford, MA 01730
Phone: PI: Topic#:	(781) 275-9535 Dr. Kevin F. Wall NAVY 01-006 Selected for Award
Title:	Visible, diode-array illuminator
Abstract:	Diode-laser arrays operating in the visible region of the spectrum offer advantages for illuminator applications, particularly for night and water penetration capability. Recent developments in diode-laser materials allow operation throughout the visible spectrum. At this time, red diode-laser technology is more mature than the existing blue-green or violet diode-laser technology. The novel aspect of this work is the use of recent advances in monolithic silicon microchannel coolers to produce two-dimensional, red, diode-laser arrays. Cylindrical microlenses can be added to the two-dimensional arrays to create high-brightness sources. The initial work in the Phase I program will focus on the production and characterization of linear diode arrays suitable for use in 2D arrays. We will investigate the tradeoffs involved in operating at the shortest possible red wavelengths.At the conclusion of a Phase II program, we would be able to introduce stacked bars commercially. The markets that could be addressed are diode laser pump sources for solid-state lasers and materials processing using the diode lasers directly. Red diode laser arrays also address the photodynamic therapy market for cancer treatment.

XYBION CORP. 240 Cedar Knolls Road Cedar Knolls, NJ 07927
Phone: PI: Topic#:	(858) 566-8050 Dr. James Pierre Hauck, Ph.D. NAVY 01-006 Selected for Award
Title:	Blue-Green Laser Illumination System Study (BLISS)
Abstract:	This project will be devoted to the development of an illuminator technology suitable for use in underwater imaging applications. While there are a number of extant technologies, we will focus on new technologies that may provide higher efficiency, lower cost, and reduced size and weight. A variety of illuminator technologies will be investigated, and compared to requirements derived from analyses of the underwater imaging application, and from platform properties. The illuminator technologies to be investigated include emitter technology, pulse power technology, and optical beam projection technology including the capabilities for varying the beam divergence (zoom). We will focus on new and emerging technologies such as Frequency Doubled Diode Pumped Vertical Cavity Surface Emitting Lasers (SHG DP-VCELS), and Electrically Pumped Two Triode Organic Lasers (TTOLs) such as the Tetracence TTOL (TcubedOL). Other candidates will be sought as well.The major advantage of this approach is to be able to illuminate underwater objects from unmanned platforms. A secondary advantage is that the sources will be low cost. A tertiary advantage is that the beam will be zoomable, allowing adaptation of the illumination to allow deeper water penetration. The use on unmanned platforms allows these systems to used in a RPV, the low cost feature allows the imaging to be performed from expendable platforms, and zoom is an additional feature that allows the platform altitude or water penetration depth to be adjusted as necessary. Thus applications such as search and rescue, airborne reconnaissance, imaging for surveillance and security, (coastal through fog), and many others would be feasible.

DIGITAL SYSTEM RESOURCES, INC. 12450 Fair Lakes Circle, Suite 500 Fairfax, VA 22033
Phone: PI: Topic#:	(714) 279-3070 Mr. Michael Cox NAVY 01-008 Selected for Award
Title:	Automatic Test Equipment (ATE) Commercial-Off-the-Shelf (COTS) Replacement for Obsolete Instruments
Abstract:	This SBIR is concerned with extending the service life of existing automated test equipment (ATE) and their associated test program sets. A number of legacy ATE systems will continue to be used for the foreseeable future. The support costs for these systems continue to escalate as they near or pass their intended service lives. SBIR N01-008 addresses the problem with the introduction of commercial-off-the-shelf (COTS) instrumentation and processing equipment. DSR's proposed product can provide a form, fit, and functional replacement of the obsolete instrument that minimizes impacts to the existing ATE (hardware and software) and to the test program sets (hardware and software). The DSR proposed product includes several innovative features to capture software design requirements, to validate ATE operation after replacement, and to assist in the resolution of test program tolerance issues.The thrust of this proposal is to develop these innovations for the ATE application, define the product architecture, and to perform a top level design for a sample instrument to validate the concepts.Completion of this effort (Phase I and Phase II) will lead directly to a reduction of Navy ATE support costs through the replacement of obsolete instrumentation. Capability could also be applied to other military or civilian test systems.

VEKTREX ELECTRONIC SYSTEMS, INC. 10225 Barnes Canyon Road, Suite A213 San Diego, CA 92121
Phone: PI: Topic#:	(858) 558-8282 Mr. Jef Hulett NAVY 01-008 Selected for Award
Title:	Automatic Test Equipment (ATE) Commercial-Off-the-Shelf (COTS) Replacement for Obsolete Instruments
Abstract:	Test equipment obsolescence in Department Of Defense (DoD) Automatic Test Equipment (ATE) is a major problem. Many of these systems currently operating were designed and built decades ago. As these systems age their individual test instruments are subject to increasing failure rates. Simultaneously, manufacturer support for these devices is diminishing. Consequently, many complex ATE instruments have, or will, become the problem-prone "system degraders" tracked in ATE program reviews. New Commercial Off-The-Shelf (COTS) instruments would ideally replace these obsolete instruments. However, integration of the new COTS instruments into existing ATE systems presents several challenges. These challenges result from incompatible communication protocols and interface busses, functional differences in the way instruments operate, mechanical packaging changes, and calibration differences. This proposal presents a plan to research and develop a methodology for implementation of a translator module to act as a bridge between the new COTS instrument and the existing ATE system. This translator module, in combination with the new COTS instrument, forms a Composite Replacement Instrument that exactly mimics the function of the original obsolete instrument. This scheme will eliminate many of the integration challenges associated with replacing obsolete instruments in military ATE systems, greatly reducing the cost and complexity of upgrades. The composite replacement instrument has widespread application in civilian and military organizations utilizing ATE systems. As test equipment integrated into ATE systems is obsoleted, it must be replaced. However, integration of new COTS instruments into existing ATE systems presents several challenges. These challenges result from incompatible communication protocols and interface busses, functional differences in the way instruments operate, mechanical packaging changes, and calibration differences. The composite replacement instrument will exactly mimic the obsoleted test equipment. This provides a few benefits. First, it creates a link between legacy ATE and test instrument replacements, which improves ATE flexibility and reduces total upgrade costs. Second, it enables replacement of obsoleted equipment without modification of existing application software. Third, since the ATE interface will not change, no operator training is required. Last, since the functionality of the replaced instrument is not altered, expensive system verification tests are not required.

APPLIED SIGNAL & IMAGE TECHNOLOGY 303 Najoles Road, Suite 104 Millersville, MD 21108
Phone: PI: Topic#:	(410) 729-3108 Mr. John J. Schveibinz NAVY 01-009 Selected for Award
Title:	Low-Cost Sonobuoy Geographic Position Locator
Abstract:	Precise geolocation of deployed sonobuoys is a standing requirement of the U.S. Navy for improving ASW operations. Current approaches to sonobuoy localization often require close over-flight of the sonobuoy by the monitoring aircraft. This compromises the security of the aircraft, and does not provide a precision result. There is a obvious need for a Sonobuoy Geolocation System that has the following characteristics: 1) ability to operate at significant (50 - 100 mile) standoff distances, 2) geolocation of multiple sonobuoys simultaneously, 3) precise location to within 100 meters, 4) low cost @ $50.00 per sonobuoy in production, 5) low probability of intercept and detection, and 6) not susceptible to narrowband jamming. Under Phase I of this effort, ASIT will refine its preliminary system design, for precision geolocation of sonobuoys, at an extremely low cost per system. The novel solution that is proposed specifically does not incorporate Global Positioning System (GPS) receivers on each sonobuoy, but does take advantage of Direct Sequence Spread Spectrum (DSSS) signals to determine precise range and geolocation. The use of low-cost commercial wireless technology is key to the success of the program. During this effort, ASIT proposes to make the design a reality by building a prototype sonobuoy geolocation system that will be ready for demonstration to the customer by the end of the Phase I effort.To address both Government and commercial needs for low-cost, robust, precision geolocation, this effort will use spread spectrum signal processing technology combined with exisiting commercial wireless components to provide a reliable geographic position locator.

NAVSYS CORP. 14960 Woodcarver Road Colorado Springs, CO 80921
Phone: PI: Topic#:	(719) 481-4877 Ms. Alison Brown NAVY 01-009 Selected for Award
Title:	Low-Cost Sonobuoy Geographic Position Locator
Abstract:	Under this proposed SBIR effort, NAVSYS will develop a design for a low cost sonobuoy position locator using GPS geolocation technology. GPS has been proposed as an alternative for sonobuoy geolocation, but the environment and DoD security requirements leads to problems with a conventional GPS approach. SAASM compatible OEM modules that prove P(Y) code tracking capability are prohibitively expensive for "disposable" applications such as sonobuoy geolocation. NAVSYS have developed a low cost tracking technology, TIDGETTM, which uses a client/server approach to reduce the functionality needed on the GPS geolocation sensor. This has been previously demonstrated with C/A code operation, installed on a sonobuoy provided by DERA Farnborough. Under this SBIR effort we propose to the develop a P(Y) code TIDGET architecture suitable for installation in US sonobuoys. A feasibility study will be performed to very the performance, physical and cost goals, and test results will be provided demonstrating the P(Y) code geolocation performance using live GPS satellite signals. Under Phase II, a prototype P(Y) code GPS sensor integrated with a government furnished sonobuoy will be .delivered for field testing. The low cost P(Y) TIDGET sensor will provide a cost effective geolocation alternative for sonobuoy applications while meeting the DoD PPS security requirements. Other applications include GPS tracking of radiosondes, for wind-finding support of DoD missions, and geolocation of low cost "smart-sensors" deployed for surveillance applications.

COMPUTER SCIENCE & APPLICATIONS 2 Clifford Drive Shalimar, FL 32579
Phone: PI: Topic#:	(850) 651-4991 Mr. Jack Lippert NAVY 01-010 Selected for Award
Title:	Large Format Resistive Arrays (LFRA) for Infrared Scene Projectors (IRSP)
Abstract:	This proposal is to demonstrate the feasibility of a larger format resistor emitter array, greater than 544x672 pixels. Mega-pixel IR/EO emitter arrays allow higher resolution imagery to be utilized in the testing and performance evaluation of advanced IR array sensors. As both the pixel count and the framerate capability of these sensors increase, the data rate required by the large emitters strain the state-of-the-art. This large format array is to be compatible with, and test, a next generation high-speed scene projector drive electronics, being developed via a FY-1999-2 SBIR topic program, capable of processing real-time image data at rates exceeding 420 MB/sec, roughly 200 Hz for a 1024x1024 array. Use with the GFE electronics set dictates that the "array" for this proposed SBIR effort is defined as all of the necessary components and assemblies from the output interface of the GFE drive electronics to the emitting pixel itself. Besides transforming the digital electronic data into a compatible set of integrated analog voltage singles to drive the array, an additional set of requirements will be dictated by ramifications from the larger array size, packaging needs, and potentially new operational regimes.The large format resistor array increases, simultaneously, the total field of view and resolution with which infrared scenes can be projected to test hardware in the loop simulations. The image quality is realistic to the point that todays IR seekers cannot distinguish the difference, allowing for acurate testing in a cost saving simulation versus flight test. Many hundreds of tests can be executed for the cost and time involved in a single flight test.

INDIGO SYSTEMS CORP. 5385 Hollister Ave #103 Santa Barbara, CA 93111
Phone: PI: Topic#:	(805) 690-6643 Mr. James T. Woolaway NAVY 01-010 Selected for Award
Title:	Large Format Resistive Arrays (LFRA) for Infrared Scene Projectors (IRSP)
Abstract:	Indigo Systems proposes to design and produce a 1024x2048 format high performance Large Format Resistive Array (LFRA) for Infrared Scene Projector (IRSP) applications. The proposed project will leverage Indigo's recently developed 512x512 MIRAGE commercial off-the-shelf (COTS) micro-emitter array technology. Additionally, to the extent possible, our current development activities for a 1024x1024 LFRA will be leveraged to insure project synergy and success. PHASE I: During phase 1 Indigo proposes to advance the 1024x2048 LFRA design from concept through the preliminary design stage of the Indigo detailed integrated circuit design process. During this activity the requirements and specifications for the device will be developed. Complete schematics of the different functional blocks and signal chain will be simulated and evaluated. The outcome of this phase is the Preliminary Design of the ROIC, including concepts studied and an interface description for a high bandwidth scene projector system during. This effort will last 4 months. PHASE I Option: The Phase I continuation (Phase I Option) will last 2 months during which time Indigo will begin the detailed design process for the 1024x2048 LFRA. The outcome will be an Interim Design Report. The objective of the proposed 1024x2048 LFRA development activity is to begin to produce the next generation in LFRA devices for scene stimulation. The current generation of IRSPs using resistive arrays contain on the order of 512x512 emitter pixels. These devices are introducing performance limitations in the testing of many modern currently fielded sensor systems. They do not provide the necessary resolution and FOV coverage to adequately test advanced sensors that are currently under development (i.e., advanced target acquisition sensors, threat warning sensors, IR search and track sensors, surveillance and reconnaissance sensors, and missile seekers). This project will facilitate the transition of existing mature resistive array technology to larger format resistive array based IRSPs for testing next generation IR sensor systems that will require testing in FY01-03.

ANACAPA SCIENCES, INC. 301 East Carrillo Street 2FL Santa Barbara, CA 93101
Phone: PI: Topic#:	(805) 966-6157 Dr. Alan Spiker NAVY 01-011 Selected for Award
Title:	Web-Based and Traditional Classroom Lesson Design Guide
Abstract:	The purpose of this SBIR is to develop and evaluate a Web-based instructional tool (WBIT) that can be used by officers and enlisted personnel to design courseware for traditional classrooms and distance learning environments. The WBIT will be organized around the five phases of ISD/SAT (analysis, design, development, implementation, and evaluation), and will provide the user with access to state-of-the-art principles of effective lesson design. The latter will reside in a powerful relational database management system forming the knowledge engine of the system. The primary products of Phase I will be a well-developed database of instructional design principles, a demonstration module, and the functional requirements for a complete system. For Phase II, the literature review will be expanded, functionality for the system will be enhanced to encompass all five phases of ISD, and experimentation with various configurations of web-hosting will be employed. The resulting product will be a powerful web-based instructional tool that can guide even novice developers through the complex ISD/SAT process.Benefits of the tool will include faster courseware development, more effective and interesting courseware materials, greater standardization and quality control of courseware, and greater integration of effective classroom techniques with the latest developments in web-based training. These attributes will be combined to produce a more optimized learning environment for student users. Upon conclusion of Phase II, the tool may be deployed either as an adjunct to MIL-HDBK-29612-2 or as a stand-alone system. The principles embodied in this system may be effectively exploited within any industry where a Systematic Approach to Training (SAT) is employed, such as Power Generation, Transportation, and Process Control.

APTIMA, INC. 12 Gill Street, Suite 1400 Woburn, MA 01801
Phone: PI: Topic#:	(781) 935-3966 Dr. Kathy Hess NAVY 01-011 Selected for Award
Title:	Guide for Instructional Design (GuIDe)
Abstract:	Technological advances (e.g., advanced electronic classrooms, video tele-training, and web-based curricula), quickly being incorporated into instructional environments, offer the instructor increased flexibility. To maximize learning we must explore not only technology but the multiple factors that impact training effectiveness. It is not enough to simply incorporate the most recent technological advances into traditional instruction, for doing so does not guarantee an optimal learning, or training, environment. Instead, planning an instructional program requires careful selection of the optimal technology and training mode out of the myriad available. For our Phase I effort we propose to develop a thorough taxonomy of learning issues, based on contemporary cognitive theory and practical training issues, that defines each issue, describes when it is most likely to be a problem and outlines what can be done to maximize the effectiveness of the instruction; this taxonomy will be used to develop a proof-of-concept web-based Guide to Instructional Development (GuIDe) that will help instructors develop the optimal training/instructional environment for their circumstances. Our unique inter-disciplinary combination of expertise and experience, ranging from innovative military training research to hands-on teaching experience in web-based environments, makes us exceptionally well qualified to address the challenge of creating an instructional development guide.A flexible and upgradeable web-based tool instructors can use to develop the optimal instructional environment for their circumstances will be valuable to government, academe, and industry as instructor?s seek to use only that technology that enhances learning.

INTELLIGENT AUTOMATION, INC. 7519 Standish Place, Suite 200 Rockville, MD 20855
Phone: PI: Topic#:	(301) 590-3155 Dr. Jacqueline Haynes NAVY 01-011 Selected for Award
Title:	Instructional Designer's Workbench
Abstract:	Intelligent Automation, Inc. (IAI) proposes to design The Instructional Designer's Workbench (IDW), an expert system that incorporates an extensive set of rules and heuristics derived from (1) research literature; (2) the advice of successful, expert instructors; and (3) policy and parameters set by the Navy. This automated tool will support courseware authors by advising the author on relevant cognitive issues and learning principles and how they should impact design of instruction. An instructional designer will use this tool as he/she considers and implements the design for an instructional program. IDW complements the Instructional Systems Design (ISD) process, advising the designer throughout the stages of the process. As a tool that provides expertise in pedagogy and psychology, IDW will strongly influence the quality and effectiveness of instruction in environments where courseware developers may not have a level of theoretical expertise to inform the development decisions they are asked to make. Regardless of the instructional delivery platform (including classrooms), IDW will be designed to answer queries about design, using cognitive learning principles, pedagogy, and relevant examples of instructional intervention. We believe that the potential for commercialization of our product is closely tied to the rapid growth of the computer-based training (CBT) and distance learning markets. As a participant in the Advanced Distributed Learning Initiative sponsored by OSD, we are keenly aware of the explosive growth and interest in distributed learning systems used in a distance-learning context. We believe that the issue of quality becomes critical in a Web environment, where materials "published" directly by authors have not been subject to the same rigor of professional quality review that most commercial products undergo prior to publication. Therefore, our product will also be marketed to purchasers of CBT and distance learning technologies as a method of reviewing courseware for the quality of its design in terms of cognitive science attributes.

TEKNOWLEDGE CORP. 1810 Embarcadero Rd Palo Alto, CA 94303
Phone: PI: Topic#:	(703) 352-9300 Dr. Michelle Sams NAVY 01-011 Selected for Award
Title:	Web-Based and Traditional Classroom Lesson Design Guide
Abstract:	Current military handbooks primarily focus on instructor-led training. This project will develop an Instructional Design Advisor and Guide for computer- and web-based training. Phase I will be an analysis of the existing literature and initial recommendation of an effective methodology/algorithm that will: 1) recommend an effective instructional method(s) based on situational factors and 2) provide clear, concise guidance on how to design the interactive courseware for a particular lesson. The analysis will compare areas such as instructional technology, learning theory, cognitive psychology, distance learning, human-computer interaction, and lessons learned from practitioners. Research gaps will be identified. Phase II will develop the decision matrix and specific design guidance. The design guidance will be provided in Military Handbook format and also delivered in a computer-based decision aid and instructional design tool. A Phase III effort would focus on developing a knowledge-based agent advisor.Distributed learning technologies are critical components of the goal to provide learning, any time, anywhere. However, the rush to convert courses to the computer or Internet has put the focus on delivery rather than design. The Instructional Design Advisor will provide novice designers with the information they need to develop computer-based lessons that are instructionally effective.

BPW, INC. 35 Curle Road Hampton, VA 23669
Phone: PI: Topic#:	(757) 850-8679 Mr. Jack Morris NAVY 01-012 Selected for Award
Title:	The Development of an Electrical Wire Chafing Protective Technology for Aircraft
Abstract:	This Small Business Innovation Research Phase 1 project describes a patented sensor technology that BPW Incorporated has developed. This technology which is called "ShortWatch," can offer significant improvements in electrical safety. The sensor consists of a temperature and mechanical damage-sensing strip distributed along the length of an electrical wire or distributed along the surfaces of an electrical component. The sensor strip performs three tasks: (1) It senses an overtemperature condition at any point along the length or surface of the electrical wire or cable, (2) It acts as a mechanical damage sensor by sensing continuity in the sensor strip distributed in the electrical cable insulation, (3) It can monitor or check the insulation effectiveness remotely without disturbing or accessing the electrical wiring. Mechanical damage (or deterioration) of the insulation or casing which might expose the energized conductors will result in loss of continuity of the sensor strip and would provide an alarm and/or interrupt power to the component, or warn the operator of a potential problem. This particular SBIR project focuses on developing the technology to protect existing aerospace wiring from chafing or external mechanical damage.We believe that the proposed "ShortWatch" technology would have very broad usage in both aerospace and non-aerospace applications. We foresee the initial applications of this technology in high-risk, high-value applications, which would include aerospace, nuclear power, and oil and gas electrical apparatus. The application of this technology for the residential and low-risk industrial usage would come later as the development costs were amortized.

INNOVATIVE DYNAMICS, INC. 2560 North Triphammer Road Ithaca, NY 14850
Phone: PI: Topic#:	(607) 257-0533 Mr. Jack Edmonds NAVY 01-012 Selected for Award
Title:	Wire Chafing Diagnostic Technology for Aircraft
Abstract:	IDI proposes to investigate passive diagnostic approaches for the detection of wire chafing on the aircraft well before exposure of the bare conductor. Conventional methods involve assessing the reduction in dielectric breakdown of the worn insulation, time domain reflectometry, or other methods that require disconnecting the cable either for access or for circuit protection. The proposed approach uses passive sensors to monitor the chafing action without removing or disconnecting the wires under reviewuation. Noise generated by the chafing can be statistically related to structural vibrations, and the chafing source can be located through signal correlation techniques. Phase I will investigate candidate passive diagnostic approaches. Lab testing on wires in a simulated chafing environment will be performed to validate the approach. Based on the test results, a down select of the preferred measurement approach will be made. Phase II will develop a functional prototype and in-situ demonstration. During the commercialization phase, IDI will work with established HUMS manufacturers to integrate the wire chafing technology into an aircraft health monitoring system. Incorporation of the in-situ wire chafing diagnostic technology into an aircraft health monitoring system will increase the safety and readiness of both military and commercial aircraft fleets. Signification life cycle cost savings could be realized with a reduction of aircraft accidents as well as reduced downtime for inspection, maintenance, and repairs. Such a system could be commercialized to detect wire chafing in space, sea, and land vehicles as well.

MATERIALS TECHNOLOGIES CORP. 57 Maryanne Dr. Monroe, CT 06468
Phone: PI: Topic#:	(203) 874-3100 Dr. YOGESH MEHROTRA NAVY 01-012 Selected for Award
Title:	THERMOGRAPHY TO THE RESCUE: WIRING SYSTEMS DIAGNOSTICS AND PROGNOSTICS
Abstract:	An urgent need exists for diagnostic methods to interrogate wiring of a Navy air vehicle on demand and assess its current health. While naval craft remains in an active status, its wiring materials, particularly insulation, interact with a complex operating environment which accelerates its aging/degradation, especially in the hostile engine environment. Ability to determine if the wire has undergone excessive degradation to warrant its replacement has direct implications on (i) aircraft operation safety and (ii) maintenance cost and the cost of ownership. We propose to place a miniature infrared sensor in a suitable location within each CRITICAL zone or compartment of an aircraft. IR sensor will continuously monitor all the wiring in that zone and send real time data to the flight crew via a single video cable. Under normal flight conditions, any defect in the wiring would manifest itself as a hot spot. Such a thermal disturbance would be instantaneously detected by our high resolution IR sensor and a signal sent in real time while in flight to alert the crew to a wiring problem in that specific area. This instantaneous determination of defects would eliminate the need for ground personnel to spend hours trying to find the defect. Visual images of wiring problems may be recorded on a pocket size videorecorder to monitor the rate of progression of the defect and then "objectively" determine the remaining useful lifeMilitary and commercial aircraft maintenance; chemical plants with explosive and/or corrosive environment; boiler rooms in public buildings; nuclear power plants

FLIGHT TECHNOLOGY INTERNATIONAL, INC. 1571 Airport Road Charlottesville, VA 22911
Phone: PI: Topic#:	(804) 978-4359 Mr. Gary Kuehn NAVY 01-013 Selected for Award
Title:	Mid-Air Collision Avoidance System (MCAS) Using Mode 5
Abstract:	FTI will research the present need for MCAS by integration of an IFF Mode 5 waveform to provide collision avoidance capabilities for the Navy platform. We will evaluate current transponder hardwares to determine the change/modification requirements necessary for such integration. Also included will be studies of current military systems, hardware and software currently in use, and the technical and functional limitations and restraints required to implement Mode 5 MCAS functions into the IFF transponders. We will provide our solutions in a functional block diagram, including the necessary interfaces and options selected.The commercial potential of this research will be to provide collision avoidance via MCAS using Mode 5, for general, commercial, and NATO aviation. This will provide for greater safety world-wide, and enhance NATO applications as well as increase sales potential to foreign militaries and individuals.

SCIENTIFIC RESEARCH CORP. 2300 Windy Ridge Parkway, Suite 400 South Atlanta, GA 30339
Phone: PI: Topic#:	(770) 989-9492 Mr. Ray Wallenmaier NAVY 01-013 Selected for Award
Title:	Mid-Air Collision Avoidance System (MCAS) Using Mode 5
Abstract:	Scientific Research Corporation (SRC) proposes to use the Identification Friend or Foe (IFF) Mode 5 Waveform set in the design of a secure high capacity Mid-Air Collision Avoidance System (MCAS). The investigation into the design of MCAS will focus on incorporating the functionality of a collision avoidance system (CAS) upon an existing Government approved Mode 5 IFF Transponder, such as the BAE System's CXP unit. Therefore, the implementation strategy for MCAS is via software. MCAS will provide security provisions such that the data link can not be easily exploited, constant monitoring of the situational awareness of the platform's safety zone, and transparency as not to affect the operational capabilities of the platform that MCAS will be installed on. MCAS will also provide a high degree of "user-friendliness" as not to interfere in any manner with the pilot's ability to successfully complete the intended mission. By embedding MCAS into a Government approved Mode 5 IFF Transponder no additional equipment needs to be installed onto the platform such as the F/A-18F. This design approach offers minimal risk to the Government by minimizing the costs associated with installing a stand-alone commercially available CAS system such as TCAS that offers no security provisions.Since MCAS will be embedded into a Government approved Mode 5 IFF Transponder, MCAS immediately can be used in joint U.S. service training exercises and operations with negligible multi-service integration concerns as well as between U.S. and armed forces of current and future members of NATO. MCAS can also be installed in privately owned aircraft as well as small and mid-size aviation firms without major retrofits to their aircraft or without causing any security breaches for military platforms.

APPLIED HYDRO-ACOUSTICS RESEARCH 15825 Shady Grove Road, Suite 135 Rockville, MD 20850
Phone: PI: Topic#:	(703) 218-3249 Mr. Robert Blanchard NAVY 01-014 Selected for Award
Title:	Environmental Assessments and Mitigation of Naval Operations
Abstract:	The objectives of this research are to research and design the necessary components of an environmental impact assessment software suite and to provide modeled environmental impact assessment results for selected sites. The research will focus on the impact of active acoustic emissions on marine mammals in the oceans. In the research and design portions of the study, AHA will examine the pertinent marine mammal characteristics and develop a database for those characteristics; retrieve and perform statistical analysis of environmental acoustic characteristics of the oceans, including temporal, spatial, and directional variability; investigate active sound propagation and procedures for the assessment of its impact on marine mammals; and incorporate the above items in the design of a web-enabled environmental assessment decision aid software tool. In the assessment portion of the research, AHA will perform acoustic modeling to produce representative summaries of marine mammal impact for selected sites.Many organizations within the U.S. government and private industry could make use of the environmental assessment software tool designed as part of this research, in order to ensure compliance with applicable laws. Examples include companies involved in drilling and recovery of natural resources, underwater construction, oceanic transportation, and marine geophysical and seismic surveying.

APPLIED ORDNANCE TECHNOLOGY 103 Paul Mellon Court, Suite A Waldorf, MD 20602
Phone: PI: Topic#:	(301) 843-4045 Andy Rogers NAVY 01-014 Selected for Award
Title:	Environmental Assessments and Mitigation of Naval Operations (Air and Surface)
Abstract:	A marine environmental compliance and analysis web-enabled toolset will be designed based on extensive prior experience with web and GIS enabled technologies in an environmental analysis and documentation environment. The objective of this research project is to develop an environmental tool capable of efficiently ensuring that the Navy has limited environmental impacts on the marine environment, while maintaining its force readiness and testing and evaluation programs. The toolset will consist of two parts. Part 1 will use existing data, acquisition policy documents, regulations and document design specifications to produce draft NEPA documents based on project requirements that are comparable to previous proposed actions. Part 2 will provide analysis tools for evaluating systems, sub systems, and technology at various stages in the acquisition lifecycle and the corresponding actions that are planned (tests, fielding, OPEVAL, etc). Two key features define this product. One: all the data is cross-referenced by the action or equipment being used, the resource impacted, the location of the action, time of year, the environmental standard operating procedures and regulations. Two: all documents and methods included at the outset will reference approved data, so that new documents can be built using approved language and methods. As changes occur in regulations, approved language and methods, these data will update automatically with minor software enhancements.Broad applicability for the resultant product is anticipated, both within the Navy and in the general environmental community. Any organization doing environmental analysis and documentation will benefit directly from a tool that allows quick and accurate access to previous related documentation. Although the content would change, no release of Navy information would occur, and the design would be useful elsewhere.

DIGITAL SYSTEM RESOURCES, INC. 12450 Fair Lakes Circle, Suite 500 Fairfax, VA 22033
Phone: PI: Topic#:	(714) 279-3054 Mr. Ronald Borrell NAVY 01-014 Selected for Award
Title:	Environmental Assessments and Mitigation of Naval Operations (Air and Surface)
Abstract:	SBIR N00-014 addresses the problem of developing a tool that can provide environmental assessments in support of the deployment and operation of active sonar systems. DSR's proposed product will initially target support of the SH-60R Airborne Low Frequency Sonar (ALFS). The design of the product will be modular so that functions that address unique SH-60R characteristics are easily separable from the basic environmental assessment capability. The proposed environmental assessment capability is based on an existing product that tracks both the acoustic source and the animals' movements, estimating the incident sound intensity and resulting impact on the animals. The product interfaces to a propagation model (selected based on the particular sonar system) to characterize the acoustic propagation and combines this information with models of the migration habits, behavior and physiology of various animal species. Incorporation of information such as ocean characteristics, weather patterns and actual animal sightings are also included in the design. The product is modular enough to accommodate any acoustic propagation model and to support other sonar systems simply by modifying the functions that interface the environmental assessment functions to the unique processing algorithms, interfaces, communication channels and OMI of the selected sonar system.Completion of this effort (Phase I and Phase II) will result in development of a tool that provides an environmental assessment capability to support deployment and operation of the SH-60R acoustics system. With appropriate interface modifications, this same capability could be provided to other U.S. Navy sonar systems and commercial systems that use acoustic energy to explore or characterize the ocean

INVOCON, INC. 19221 IH-45 South; Ste. 530 Conroe, TX 77385
Phone: PI: Topic#:	(281) 292-9903 Mr. Alan Haigood NAVY 01-015 Selected for Award
Title:	Enhanced Crash Survivable Flight Incident Recorder (ECSFIR)
Abstract:	Proposed is a study of incorporation of aircraft incident recorders and Structural Data Recorder Systems (SDRS) into an open architecture wireless network. This Enhanced Crash Survivable Flight Incident Recorder (ECSFIR) will improve flight safety by providing better information to accident investigators and reduce aircraft maintenance costs by improving diagnostics and automating maintenance schedules. Invocon will conduct comprehensive investigations into the ECSFIR system expectations and technical requirements. Consideration will be given to the incorporation of microminiature wireless sensors similar to those previously developed by Invocon. Programmable Surface Acoustic Wave (PSAW) correlators are under investigation by a team including Invocon, Sandia National Laboratories, NASA, and the Air Force Research Lab; in the ECSFIR, they will provide simultaneous RF communications giving the RF data bus extremely high-speed and reliable transmissions. The system will have an open architecture for future expansion and portability between aircraft. Invocon will provide at the Phase I conclusion a report detailing conceptual designs and configuration structures for all ECSFIR elements. Invocon proposes a Phase I Option to demonstrate a prototype wireless ECSFIR aboard a Naval Aircraft. This system will perform most of the major proposed requirements and provide a proof of concept and predetermination of some Phase II obstacles. Commercial airlines are always seeking ways to reduce costs and increase safety. It is likely that the reduction in aircraft maintenance costs alone will demand a system like the proposed ECSFIR. But the market for this type of system extends far outside the aviation industry. In any setting where machinery performance is essential, and failure induced stoppage greatly affects profit, a health maintenance system is imperative and cost effective. Commercial equipment from all types of industry could benefit from component monitoring and performance evaluation: oilrigs, tractor-trailers, locomotives, and industrial equipment. A wireless health monitor like the proposed ECSFIR provides two major benefits over current monitoring systems: convenient retrofitting and acquisition from previously inaccessible areas. Often equipment is designed with unknown weaknesses, and the built-in sensors do not monitor all the critical components. Retrofitting with current wired sensors is not cost efficient, and at times impossible. A wireless system allows quick non-intrusive installation on any component. The incorporation of the microminiature wireless sensors adds one more way to reduce installation complexity and costs. In addition the ability of remote processing paves the way for real-time health monitoring and operator warning notification of potential failures or the end of the life-cycle approaching.

MANAGEMENT SCIENCES, INC. 6022 Constitution Avenue NE Albuquerque, NM 87110
Phone: PI: Topic#:	(505) 255-8611 Mr. Roger P. Case NAVY 01-015 Selected for Award
Title:	Digital Data Download (D3) with Crash Survivable Memory
Abstract:	This proposal presents innovative research that will result in a multi-purpose, crash survivable, universal flight information system and data recorder (UFDR). The UFDR will digitally process and record structural, engine/propulsion, electrical/avionics, environmental, exceedance, and event data to crash survivable memory with capacity for terrabytes of data. It will have advanced features for processing and storing voice and data from Integrated Mechanical Diagnostics and data from Aircraft Health Monitoring Sensors. This is a ��single box�� solution that offers significant function, weight, and total ownership cost advantages over current technology. The UFDR will incorporate a very high-speed transceiver with data compression algorithms that will download hours of flight data in a few minutes making it unnecessary to spend millions on ��black box�� recovery. The architecture is backwards compatible to legacy aircraft as well as future aircraft. Reduced parts count and lower power consumption will dramatically improve fielded reliability. Field Programmable Gate Arrays will provide upgradeability, programming flexibility, flight data sensor management, enhanced reliability and product longevity. This innovative approach is low cost, modular, expandable and configurable to support legacy, new and undefined requirements and communication protocols.The proposed UFDR offers reduced weight and significant cost saving with increased functionality combining the conventional Air Data Recorder, Health Usage Monitoring System, and Integrated Mechanical Diagnostics units. Based on successful completion of the UFDR research, MSI will prototype, manufacture and market the UFDR to the military and civil aviation communities. We anticipate developing strong marketing relationships with aerospace, avionics and aircraft manufacturers, owner/operators and aircraft servicing organizations. These relationships assure that the UFDR is compatible with state-of-the-art avionics design.

PHYSICAL OPTICS CORP. Information Technologies Div., 20600 Gramercy Plac Torrance, CA 90501
Phone: PI: Topic#:	(310) 320-3088 Dr. Andrew Kostrzewski NAVY 01-015 Selected for Award
Title:	Flight Anomalous Event Recorder Information Technology Open (FAERITO) Digital Data Download (D3)
Abstract:	Physical Optics Corporation (POC) proposes a new approach to Digital Data Download (D3) with Crash Survivable Memory. Based on this approach we will develop a system called Flight Anomalous Event Recorder Information Technology Open (FAERITO) D3, to collect and quickly download hours of video, audio, and sensor diagnostic data. This system will use 3400 g crash-survivable PCMCIA packaging cushioned with aerogel, which is an outstanding thermal insulator and 3400 g crush protector. The FAERITO system will be compatible with SDRS, CFSIR, and FLDR, all of which will be integrated into the single FAERITO package. The crash-survivable-memory FAERITO system will be based on non-volatile newest-generation multi-Gbyte flash memory and POC's soft-computing and soft-communication (SC2) hypercompression technology, which offers up to 4000:1 compression for TV-class video. It will enable automatic recording of anomalous events (both spatial and temporal) without a priori knowledge of the specific nature of these events. FAERITO will also incorporate wireless sensor LAN technology that is still unknown to present commercial (or military) 2G and 2.5G wireless telephony, and which is equivalent to futuristic 3G wireless units. It will provide capabilities to transfer TV-class imagery, video, imaging radar, teleconferences, and other interactive and IP video information.Many commercial applications will benefit from the diverse components and system features of FAERITO information technology, including: emerging generations of interactive wireless video (3G wireless phone), IP-video, cellular video phones, e-commerce security, video surveillance, video games, telemedicine, robotics, physical protection, video conferencing, MPEG-4, and finally, civilian FAA black-box flight data recorders.

COMPUTER OPTICS, INC. 120 Derry Road, P.O.Box 7 Hudson, NH 03051
Phone: PI: Topic#:	(603) 889-2116 Dr. Jonathan S. Kane NAVY 01-016 Selected for Award
Title:	Development of New Processes for the Refurbishment of Infrared Search and Track (IRST) Germanium (Ge) domes
Abstract:	A proprietary method is analyzed for the refurbishing IRST germanium domes that have been damaged in flight operations in adverse hostile environments which include particulates such as sand, rain., aerosols, etc. The COI technique involves removing the damaged surface and then restoring the domes on a production basis to their original focal length performance specification. Improved coating machine technology is evaluated in the application of Amorphous Diamond Like Carbon (ADLC) via a process known as Ion-Assisted Filtered Cathodic Arc, IFCAD, process coating technology to Germanium substrates operating in the 7.5 to 14 micron band. The result is a low cost refurbished dome that has a harder outer coating than the original dome and hence longer expected lifetime. The proposed research will benefit not only government programs but will also benefit existing work currently at Computer Optics Inc. The technology developed under this proposal will have direct application to laser optics, the electric power industry and construction.

GENVAC AEROSPACE CORP. 110 Alpha Park Cleveland, OH 44143
Phone: PI: Topic#:	(440) 646-9986 Mr. Laszlo Takacs NAVY 01-016 Selected for Award
Title:	Development of New Processes for the Refurbishment of Infrared Search and Track (IRST) Germanium (Ge) domes
Abstract:	A procedure has been developed to refurbish hemispherical infrared (IR) windows designed for use on the Infrared Search and Track (IRST) System. The two stage program will enable repair of the surface coated germanium (Ge) windows, more commonly known as domes, which have failed to meet IR transmission and focus specifications. Failure to meet specifications is due to a high density of pits in the aperture area generated from exposure to adverse environmental conditions at high velocities. Stage 1 (immediate) involves removal of surface material, which will result in a finished dome that meets transmission requirements with 4.7% maximum deviation from the specified focus. This process may introduce slight image aberration, which may or may not be within acceptable tolerance of the optical system. A dome refurbished using stage 1 will be delivered at the end of SBIR Phase I. Stage 2 will implement a process to add Ge to the dome surface in an amount necessary to allow resurfacing to the original design dimensions. This process would return the dome to the like-new operational performance. Feasibility for stage 2 will be demonstrated during SBIR Phase I. Delivery of domes refurbished using stage 2 would occur during SBIR Phase II. The electric power utility industry utilizes IR sensors in the same bandwidth as the IRST sensor to perform evaluation on above ground power transmission lines for insulation leaks. These leaks result in power transmission loss costing the utility companies millions of dollars annually. To identify failures in power line insulation, public utilities use specially configured aircraft that fly over the nation's power lines using IR sensors to detect the leaks. The location of the failed insulation along the power line is detected and the information sent to the power company for repair. The IR systems used in the utility company's aircraft have the same type of IR window used in an IRST system. While less harsh (lower speed), the utility company aircraft's IR system is subject to much of the same environment as the F-14D IRST. The utility companies' IR systems experience more usage than the IRST. Further, flights are made at lower altitudes where airborne particulate matter has a greater opaqueing effect on the IR window. Resulting failure of the IR window occurs at least as often in the IRST. Development of a refurbishment process can be directly applied to this particular commercial application.

NAVMAR APPLIED SCIENCES CORP. 65 West Street Road, Suite B-104 Warminster, PA 18974
Phone: PI: Topic#:	(215) 675-4900 Mr. Edward Garabed NAVY 01-017 Selected for Award
Title:	Shallow Water Bottom Characteristic Measurement Sensors
Abstract:	This SBIR proposes the design of an expendable sensor system for in-situ measurement of bottom characteristics such as bottom loss and bottom back-scatter. The data would be inputs to acoustic performance models such as Tactical Decision Aids (TDAs). This sensor system will obtain real time environmental data in shallow water to optimize the deployment and performance of acoustic sensors such as Air Deployable Active Receiver (ADAR), Advanced Low Frequency Sonar (ALFS), and Directional Command Active Sonobuoy System (DICASS). The unique features of this proposal concept are near bottom sensor strings combined with near bottom small sources to obtain bottom characteristics at low grazing angles without the need for large high power sources. The sources proposed here are only 170 (dB//uPA2 in a one-octave band) compared to the 200 to 215 (dB//uPA2 in a one-octave band) source level required by near surface measurement systems. The proposed system also utilizes an in-buoy processing system to compute bottom loss and bottom back-scatter from measurements of signal level and arrival times. Only results that can be directly input to TDA will be transmitted to tactical aircraft adding no additional processing burden on the tactical aircraft system.This proposed device will satisfy a critical need for a rapid response environmental measurement system to acquire data and in-situ measurements for accurate on site tactical decision aids, nowcast active sonar predictions and buoy deployment geometry optimization, and perform this task in a more environmentally friendly manner with smaller sources. This development will allow the measurement of ocean bottom parameters safely at sites close to shore and at sites which are off-limits to the current large source level system. Commercial markets include offshore environmental bottom sediment data collection, coastal environmental studies and potentially off shore oil exploration.

RDA, INC. P.O. Box 49 Doylestown, PA 18901
Phone: PI: Topic#:	(540) 349-8083 Mr. Ronald H. Buratti NAVY 01-017 Selected for Award
Title:	Shallow Water Bottom Characteristic Measurement Sensors
Abstract:	Detailed knowledge of the operational environment can be exploited to improve the capabilities of active sonar detection and classification systems. The deployment geometry, transmit bandwidth and averaging time can all be set to optimize detection performance given the detection system has a detailed knowledge of the operational environment. In addition, more detailed knowledge may also provide target classification clues derived from the received echo shape. The environmental data gathered on station could be integrated into a tactical decision aid (TDA) that is run prior to the start of the Anti Submarine Warfare (ASW) search phase of the mission. One of the more difficult parameters to measure in-situ is the bottom scattering strength vs. grazing angle. Knowledge of the bottom scattering strength is critical in shallow water operation where the bottom reverberation is the dominant source of interference. This is especially true in downward refracting environments. The bottom scattering strength is difficult to measure because bottom reverberation is a function of a number of complex parameters such as the transmission loss to the bottom and the bottom loss verses grazing angle curve. This SBIR solicitation (N01-017) proposes the development of a new sensor capable of making a bottom loss measurement. To keep development and production costs manageable, this new sensor will leverage heavily on existing air deployed sonobuoy technology. The proposed sensor would be used in conjunction with existing sonobuoys already in the Navy's inventory. In this SBIR solicitation we shall address the methodology and feasibility of such a technique.The product of this SBIR will have a direct impact on existing and proposed air deployed ASW search systems. The proposed system could be used either prior to the deployment of or in conjunction with existing or planned ASW search sensors. The benefit to the fleet will be an increased awareness of the operational environment leading to more effective mission planning and execution. The proposed sensor could potentially be marketable to non-military government agencies for the purpose of harbor monitoring and surveillance. More specifically, we see a potential market to drug interdiction agencies needing to detect and classify small vessels that may escape detection by radar systems yet have strong acoustic signatures.

FFF ENGINEERING DESIGN 176 Albert Street North Arlington, NJ 07032
Phone: PI: Topic#:	(201) 615-3201 Mr. Odilo Vazquez NAVY 01-018 Selected for Award
Title:	Semi-Active Side-Lateral Engine Mounts for Control of Vibration and Shock Loading
Abstract:	The objective of this proposal is to define a program that will investigate the E-2C vibration and shock dampening side engine mount requirements and develop an innovative semi-active vibration and shock mount system for the E2C aircraft's side lateral mounts. Currently, there is no system available that incorporates both vibration nulling and appreciable shock alignment in a compact package. FFF is proposing an innovative hybrid MR concept that can meet the E-2C's requirements in a package that can withstand the aerospace environmental conditions and the installation constraints.New semi active mounts can be used on many of the curent classes of aircrafts and helicopters. The combination of improving vibration isolation while maintaining static alingment under shock loads can be applicable to many commercial and miliatry programs including land vehicles and marime applications.

INTELLIGENT AUTOMATION, INC. 7519 Standish Place, Suite 200 Rockville, MD 20855
Phone: PI: Topic#:	(301) 590-3155 Dr. Leonard Haynes NAVY 01-018 Selected for Award
Title:	Side lateral Engine Mount
Abstract:	The key innovation of this proposal is combining an MR fluid damper with a stiction based shock absorber to provide adaptive damping and shock absorption as a means to upgrade the current side lateral engine mount which provides no vibration isolation. Our concept is focused on minimizing the certification process for use on E-2C and C-2A aircraft, and therefore minimizing the time and cost to being installation on actual Navy aircraft. The proposal also describes the control algorithms which will allow the system to be totally autonomous. We have organized the proposed project so that by the end of Phase 1 we will be able to test the key aspects of the system and assess the benefits with respect to adaptive damping based on MR fluid. By the end of Phase 2 we will have a fully integrated adjustable damping and shock absorbing side lateral engine mount which would be ready to begin the certification process.Our first commercialization focus will be to achieve a system which the Navy will use on E2-C and C-2A aircraft. Later commercialization will focus on other aircraft adaptive isolation mounts, and then on applications beyond aircraft.

QRDC, INC. Box 562 Excelsior, MN 55331
Phone: PI: Topic#:	(952) 556-5205 Dr. Daryoush Allaei NAVY 01-018 Selected for Award
Title:	Smart Engine Mounts with Energy Managing Continuous Structural Elements
Abstract:	Vibration and shock attenuation is the focus of this SBIR project. We offer to demonstrate the feasibility of the Smart Engine Mount with Energy Managing Continuous Structural Elements system concept suitable for use in airborne vehicles such as E-2C aircraft. Excess vibration energies will be channeled and attenuated inside the Smart Engine Mount whose continuous and connected elements will have energy flow control and energy managing capabilities. This innovative Smart Engine Mount concept may be used as an effective semi-active and hybrid barrier between vibration energy generated by an engine and sensitive optical and electrical components inside an aircraft. The entire smart mount will be composed of three main layers in which semi-active and hybrid energy-managing elements will be embedded. In other word, vibration and shock disturbances injected into the engine mounts will be confined, diverted, converted, absorbed, steered, and dissipated using embedded passive elements and active actuators. It is this energy-managing feature of the smart mount that makes our concept unique and effective. In addition, our approach will be distinct when compared with conventional discrete mounts because our smart mount will be made of continuous elements that are interconnected to make the entire mount system significantly more effective. Finally, the semi-active feature of the proposed Smart Engine Mount will have the capability of changing it stiffness and/or damping rates in an on-off manner to accommodate operational changes.More effective engine mounts may be used on many of the current commercial piston and turboprop aircraft as well as helicopters. The combination of improved vibration isolation while maintaining static alignment conditions under shock loads will also be applicable to better isolating a variety of military and commercial power trains from the rest of the vehicle. In addition to airborne types, these vehicles include passenger automobiles, commercial trucks, marine vehicles such as submarines and surface ships.

ADVANCED ROTORCRAFT TECHNOLOGY, INC. 1685 Plymouth Street, Suite 250 Mountain View, CA 94043
Phone: PI: Topic#:	(650) 968-1464 Dr. Chengjian He NAVY 01-019 Selected for Award
Title:	Advanced Rotorcraft Shipboard Landing Aerodynamic Interference Software Modules
Abstract:	Shipboard landing presents a multitude of problems for rotorcraft that must be addressed to assure safe operation. The interaction of the rotor downwash with the ship's deck and the interaction of the ship airwake with the rotor are two key areas of this "Dynamic Interface" that must be fully evaluated to establish limits on shipboard operations for rotorcraft. The high cost and inherent danger of shipboard testing have been major impediments to supporting the Fleet in this critical area. The use of simulation to provide a Rotorcraft Shipboard Operational Limit Prediction Tool will enhance flight test productivity, reduce cost, and increase the safety of flight test operations. Advanced Rotorcraft Technology Inc. (ART) has developed FLIGHTLAB, a comprehensive rotorcraft modeling tool, and has added extensive utilities to support flight testing and validation. Under this SBIR, ART proposes to extend the aerodynamic and interference modeling in FLIGHTLAB to fully encompass the shipboard landing environment and to incorporate automated prediction of the Rotorcraft Shipboard Operating Limits and a prototype Maritime version of the ADS -33 Handling Qualities analysis. The resulting Rotorcraft Shipboard Operational Limit Prediction Tool will greatly facilitate the test and evaluation of helicopter shipboard landing. The tool developed will expedite rotorcraft/ship qualification, benefit both military and commercial rotorcraft shipboard landing training, and facilitate commercial airline landing zone planning.

CONTINUUM DYNAMICS, INC. 34 Lexington Avenue Ewing, NJ 08618
Phone: PI: Topic#:	(609) 538-0444 Dr. Robert M. McKillip, Jr. NAVY 01-019 Selected for Award
Title:	A Real-Time Airwake Model for Dynamic Interface Simulation Support
Abstract:	A novel physics-based real-time computational method of representing the airwake of Navy ships to support rotorcraft shipboard landing simulation studies is proposed for research and development. In this method, the unsteady ship airwake is modeled using vortex doublet elements shed from sharp edges of the ship superstructure, and the approaching rotorcraft is described by a panel-based fuselage model and freely distorting wake analysis. Use of fast panel methods and octree sorting structures may allow this highly complex wake representation to be calculated in real-time, using networked computers in a parallel computation environment. The airwake model representation provides an appropriately detailed level of fidelity to capture handling qualities features of importance to shipboard rotary-wing aircraft operations, while maintaining real-time computation throughput. This approach promises to revolutionize "dynamic interface" simulation by combining physics-based models of helicopter flight dynamics, rotorcraft free wake representations, unsteady ship airwake generation, and, optionally, ship motion dynamics. The resulting simulation environment may be used to quantify operational shipboard approach envelopes without the considerable time and expense of at-sea testing.Software developed under the proposed program would drastically reduce Navy costs associated with at-sea qualification testing of various ship/rotorcraft combinations, by replacing a significant number of tests with computer simulation. The airwake software would also enhance the safety of commericial helicopter pilots operating from offshore oil platforms or in urban environments when used with flight simulator systems.

GALORATH, INC. 100 North Sepulveda Blvd, Suite 1801 El Segundo, CA 90245
Phone: PI: Topic#:	(310) 414-3222 Mr. Dan Galorath NAVY 01-020 Awarded: 07MAR01
Title:	Software Cost and Schedule Estimating
Abstract:	There is an acute need for the development of software estimation techniques that will allow government organizations and contractors to realistically determine the scope of software development projects up-front and to refine these estimates and make project decisions during development based on quantified estimates and risk assessments. This information is needed on new developments, upgrades and maintenance for the variety of languages and methods used within NAVAIR and the Department of Defense, as well as a broad range of other government and commercial organizations. Research by the Navy and others has identified realistic software estimation as a "Best Practice". Galorath proposes "plug-ins" to its commercial SEER models that will considerably enhance the state of the art in software project estimation and tracking. Plug-ins will include data mining and other techniques, a database of project histories and trends, as well as tighter integration of project management functionality. Once this SBIR is successfully completed, users will be able to: � Estimate software development cost, schedule, and risk with more accuracy, early in the acquisition cycle. � Better evaluate risks and make informed decisions both early and throughout the project. � Better prepare project "estimates to complete". GartnerGroup has identified SEER as best in class and has estimated significant growth in the software estimation tool and services market. The products resulting from this SBIR will help Galorath achieve this significant growth.

MAROTZ, INC. 13518 Jamul Drive Jamul, CA 91935
Phone: PI: Topic#:	(916) 801-8022 Mr. John Amacker NAVY 01-020 Selected for Award
Title:	Software Cost and Schedule Estimating
Abstract:	The objective of this Phase 1 proposal is to demonstrate the feasibility of developing a set of software estimation tools and procedures that will estimate software development cost and schedule for software efforts of Naval Aviation. The set of software cost and schedules estimation tools and procedures developed through this project will include Marotz, Inc.'s software estimation tool Cost Xpert. The software estimation models in Cost Xpert will be customized and calibrated to reflect Naval Aviation's specific software development domain and to estimate the costs and schedules of Naval Aviation software development projects with a standard deviation of 10% or less. This set of tools will also include a tool with the ability to update Naval Aviation's project estimates and project baselines to with metrics gathered from by Naval Aviation's automated project management tools. This tool will allow Naval Aviation to record and store actual project metrics, compare actual results with estimated results, when appropriate create new project estimates or baselines, and finally correlate the metrics needed to refine and calibrate the customized Naval Aviation software estimation models.These tools and procedures hold the promise of allowing Naval Aviation to not only effectively plan for the allocation of its resources in the development of new and upgraded systems for the Fleet but also become more dynamic and systematic in its decision making processes throughout the entire lifecycle of its projects increasing the probabilities of project success. Marotz, Inc. anticipates that the same software management professionals that use its estimation tool Cost Xpert will be interested in a tool that ties together general purpose software management tools used by Naval Aviation, the estimation models in Cost Xpert 3.0 and a PERK database. It will be using its established sales channels and relationships with clients to market this tool. Marotz, Inc. estimates that a successful software process simulation tool will be achieve $500 thousand in revenue in its first year after release and $2 million in its second year.

TECHNOMICS, INC. 5290 Overpass Road #206 Santa Barbara, CA 93111
Phone: PI: Topic#:	(703) 415-1005 Mr. Richard B. Collins II NAVY 01-020 Selected for Award
Title:	Software Cost and Schedule Estimating
Abstract:	The proposal addresses development of a tool to improve software cost and schedule estimating accuracy. After collecting and building a preliminary database of historical software cost, technical, and programmatic data, we will explore application of innovative methods and techniques to use in the software estimating tool. The anticipated results of this research include: 1) an increase in the accuracy of software development and maintenance cost and schedule estimates; 2) a more realistic and defensible quantification of uncertainty (estimating error range); and 3) a reduction in the effort required to generate an estimate and calibrate the estimating tool.Our proposed software cost-estimating tool will be tailored to both the unique requirements of Department of Defense (DOD) organizations and to the unique needs of industry, including defense and other commercial concerns. Because the model will provide a more accurate and defensible cost estimate, we believe we will achieve substantial market penetration within DoD. Consequently, defense firms developing and maintaining software would then have a strong incentive to also purchase and use this model in order to: 1) determine what the government's estimate of their project will be and 2) produce an estimate that the government is more likely to consider reasonable. Because of its proposed built-in capability to tailor itself to the salient attributes of a specific software organization, the model can also be rapidly generalized for use by other commercial firms.

CONTINUUM DYNAMICS, INC. 34 Lexington Avenue Ewing, NJ 08618
Phone: PI: Topic#:	(609) 538-0444 Dr. WilliamJ. Usab, Jr. NAVY 01-021 Selected for Award
Title:	Pressure Sensitive Non-Slip Surface Appliqu� for Low Drag
Abstract:	Military and commercial aircraft use non-slip treatments on upper areas of the aircraft to provide safe walking surfaces for maintenance personnel and pilots during routine service operations and, in some cases, cockpit access. Current non-slip surface treatments for aircraft rely on fixed surface roughness to provide traction. While these surface treatments provide slip resistance, significant performance penalties in terms of aerodynamic drag can arise due to the surface roughness of these devices. Continuum Dynamics, Inc. (CDI) proposes the development of an innovative Pressure Sensitive Non-slip Surface Appliqu� (PSNSA) which is slip resistant when pressure is applied to the surface. Under aircraft flight conditions the PSNSA device has a smooth surface equivalent to aircraft skin yielding low viscous drag and improved aircraft performance relative to current surface treatments. In addition, this non-slip device offers the potential for greater slip resistance in all weather conditions reducing the risk of accidents and injury.The successful development of the proposed PSNSA concept will reduce operating costs for commercial and military aircraft by reducing drag. Additionally this device will make maintenance operations safer by providing better non-slip surfaces on aircraft wings.

TDA RESEARCH, INC. 12345 W. 52nd Ave. Wheat Ridge, CO 80033
Phone: PI: Topic#:	(303) 940-2317 Dr. Silvia Luebben NAVY 01-021 Selected for Award
Title:	Non-skid Coatings for Aircraft
Abstract:	Horizontal external surfaces on military and civil aircraft are usually treated with non-slip coatings to provide a safe pathway for maintenance personnel walking on with tools and equipment during service and repair. Current non-slip treatments are heavy and degrade the aerodynamic performance of the airplane because of their high profile. The Department of Navy is looking for a new effective slip resistant surface treatment that does not increase the drag and weight of the aircraft. In this Phase I SBIR project TDA proposes to develop a new anti-slip nanocomposite coating that is light and does not require a high-profile surface roughness to be effective. This new multicomponent material will offer good dry and wet traction and will be applied as a regular topcoat.TDA's material will have immediate application as a coating for the upper surfaces of military and commercial aircraft. Non-skid coatings have other applications including flooring for ramps, aisles, walkways, steps, handicap zones, docking stations, recreational and commercial boats; in forklifts traffic areas, around machinery and in chemical transfer zones. Industries that benefit from the use of anti-slip coatings include chemical plants and transformers, food processing plants, paper mills, hospitals, railroads and subways, wineries, sewage and treatment plants, swimming pools, schools and public facilities.

CAPE COD RESEARCH, INC. 19 Research Road East Falmouth, MA 02536
Phone: PI: Topic#:	(508) 540-4400 Mr. Francis L. Keohan NAVY 01-022 Selected for Award
Title:	Fasteners/Rivets for Watertight Integrity and Corrosion Prevention in Permanent Application
Abstract:	Military aircraft require corrosion inhibiting sealants around fasteners gaps to prevent fuel leaks, water ingress, and corrosion. Conventional selants must be wet-applied during assembly, which results in excessive labor costs and downtime. Limitations of conventional polyether and polysulfide-based sealants include: the slowness of cure below room temperature, contraction during cure, and cumbersome application methods. A novel fastener sealant based on an expandable matrix resin with microencapsulated curing agents and chrome-free anticorrosive agents is proposed for this application. The sealant is designed to be pre-applied to metallic fasteners, form a thin, dry outer film surface and remain shelf-stable. Upon insertion into a hole, the shearing forces reflow the sealant and activate the base resin curing. The curing process will be accompanied by a controlled level of material expansion for effective sealing. The proposed sealant system should effectively protect aircraft structures from water intrusion and associated corrosion processes. Pre-applied fastener sealants will be formulated with microencapsulated curing agents, low toxicity corrosion inhibitors and rheological additives and tested for adhesion to aluminum and composites, fuel and water barrier properties, resistance to thermal and chemical degradation, and corrosion inhibiting properties. The physical performance will be compared to commercial sealants meeting MIL-S-81733.A pre-applied,chrome-free, expandable sealant having excellent corrosion inhibiting properties would provide the DoD with a cost-effective process for maintaining military aircraft. Potential commercial applications would include the manufacture and repair of civilian aircraft, automotive and marine products.

METSS CORP. 720-G Lakeview Plaza Blvd. Columbus, OH 43085
Phone: PI: Topic#:	(614) 842-6600 Dr. Gideon Salee NAVY 01-022 Selected for Award
Title:	Fasteners/Rivets for Watertight Integrity and Corrosion Prevention in Permanent Application
Abstract:	During aircraft and helicopter production fasteners are currently wet installed with two-component polysulfide-sealant. Applying the two-component sealant is both time consuming and labor intensive. The excess sealant can be classified as hazardous waste. MIL-STD-7179 requires that fasteners be wet installed with sealant to secure water tightness and corrosion prevention. METSS is proposing to apply its expertise in the area of sealants, environmentally friendly corrosion inhibitors, and micro-encapsulation to develop a coating that is applied during the manufacturing process of the fastener /rivet. The dry non-toxic coating developed will provide lubricity during installation, water tightness, and comply with current environmental laws and regulations. Under the proposed program, METSS will evaluate three different approaches to obtaining this objective. These are: (a) low compression set, water repellant, elastomeric coatings; (b) Post fastening, swellable coatings; and (c) post fastening, foamable coatings. Each of these technologies is technically and commercially viable, thereby offering the potential for a near-term solution to this critical problem.The results from this Phase I program will lay the groundwork for a leak-proof, corrosion resistant coating that can be applied on a rivet or other type of fastener used by the U.S. Navy during its manufacturing and will eliminate the need to apply a wet, two-component, polysulfide sealant prior to the rivet or fastener installation. METSS expects that the proposed improvements will very significantly increase the rate of riveting, make it much less labor intensive, reduce worker exposure to hazardous chemicals, and avoid the handling and disposal of hazardous wastes. Successful completion of the research and development work, with participation by one or more potential partners, will facilitate technology transfer and insertion. Subsequent optimization and commercialization efforts by METSS and its development partner(s) will have a significant impact on the specialty fastener sector, which in turn will be able to supply the U.S. Navy, U.S. Marine Corps, and U.S. Coast Guard, as well as the U.S. Army and U.S. Air Force with commercially available corrosion resistant, fastening systems. The technology developed should have additional uses in commercial and industrial markets, for example in the automotive, marine, and building construction industry sectors.

SYSTEMS & MATERIALS RESEARCH CONSULT 113 S. Cuernavaca Austin, TX 78733
Phone: PI: Topic#:	(512) 263-0822 Dr. Alan V. Bray NAVY 01-022 Awarded: 07MAR01
Title:	Fasteners/Rivets for Watertight Integrity and Corrosion Prevention in Permanent Application
Abstract:	Polysufide sealants work well in rivets/fasteners for Naval aricraft, providing sealing and corrosion prevention functions, but their installation is problematic. The labor and waste hazardous materials associated with mixing the sealant are costly and time consuming. Systems and Materials Research (SMRC) proposes to develop a one-part polysulfide (1K-PS) nanocomposite sealant that activates with the pressure of installation. A nano-putty, containing environmentally friendly anti-corrosion additives, will be formed from COTS 1K-PS liquid by blending in nano-clays and polymeric thickeners. The nano-putty is an uncured state that will be encapsulated to prevent premature cure. The 1K-PS encapsulated nano-putty will be formed into collars and assembled onto the rivet. A full scale demonstration will be conducted at the end of Phase I on a 7075 T6 aircraft aluminum sheet test bed. SMRC has formed a Phase I alliance with a large aircraft fastners company as technical consultant and potential Phase III licensee for self-seal rivets. Southwest Texas State Univeristy, a leader in nanocomposite reserach, will provide subcontract research services, and full access to an 8500 square foot state-of-the- art materials development laboratory. A commericalization plan will be prepared in Phase I that will center on development of a licensing agreement with the Phase I commerical partner rivet manufacturer.The labor and time savings of a self-seal rivet design makes this a very attrractive commerical product. In addition to the cost savings in manufacture and maintenance, the 1K-PS nanocomposite self seal rivet will virtually eliminate hazardous waste volume while improving the reliability of the rivet seal. This improvement comes from standardizing the amount of sealant applied, and the improved sealing function that results from using a nano-clay constituent. Commericalization will be appraoched through licensing the technology to rivet manufacturing companies, with the SMRC Phase I commercial partner as the first licensing target.

MAINSTREAM ENGINEERING CORP. 200 Yellow Place, Pines Industrial Center Rockledge, FL 32955
Phone: PI: Topic#:	(321) 631-3550 Dr. Robert P. Scaringe NAVY 01-023 Selected for Award
Title:	Phase I Demonstration of a Passive Missile Environment Monitor
Abstract:	The ability to safely detect fuel leaks, salt and water intrusion, charge, shock and temperature extremes in a missile canister is lacking. Normal methods used to determine a fuel leak, moisture, charge, or exposure to extreme temperatures and shock inside a missile canister are inadequate because they require power to operate. The introduction of voltage and current into the volatile fuel vapors, no matter how small, can be catastrophic in that it can ignite the very liquid it is attempting to detect. Battery powered systems are also impractical due to the five year certification period. Mainstream has a developed a concept for a passive inexpensive non-electrical, non-mechanical sensor to perform these detection functions. This indicator does not introduce any electrical discharge when performing the monitoring. Under this Phase I effort, Mainstream will completely demonstrate the leak detector and investigate the ideal configuration for this Navy missile application. The Phase I effort includes an extensive experimental demonstration of a visual indicator for use in missile canisters. Phase I will include critical proof-of-concept experiments to demonstrate the feasibility and accuracy of the proposed monitor. This product would complement our existing line of passive system monitors and our marketing studies have indicated markets for a moisture/temperature/shock version of this monitor for the shipping industry, a charge/moisture/shock/temperature version of this indicator for the computer and electronics industries (for use in shipping and storage), and a fuel leakage indicator configuration for the energy industry.

MIDE TECHNOLOGY CORP. 56 Rogers Street Cambridge, MA 02142
Phone: PI: Topic#:	(617) 252-0660 Dr. Brett Masters NAVY 01-023 Selected for Award
Title:	Low-Cost Missile Environment Monitor
Abstract:	The determination of the environmental extremes that a sensitive piece of equipment has been exposed do during shipping and storage is of critical importance. All electronic equipment and chemicals have limitations as far as specific environmental conditions are concerned. If these specific conditions have been exceeded, serious operational problems can result. It is therefore crucial that a sensor that can determine if environmental parameters have been exceeded operates reliably over a long period. To date, most sensors operate with electrical power. This poses serious problems for sensors that need to operate over an extended period of time as batteries deplete and alternative energy sources are required. Mid� proposes a sensor array that is purely mechanical and will require no electrical power. This array of sensors will utilize the unique qualities of intelligent materials, specifically smart gels and shape memory alloys to determine if the limitations set for the humidity, temperature, shock, fuel, salt and water levels have been exceeded. This sensor will be built on proven technology and will be extremely cost effective.The smart materials environmental monitor promises substantial returns from the ability to monitor environmental conditions inside commercial shipping containers for sensitive items such as electronics. The monitor offers an inexpensive and easy-to-use solution to check for and ameliorate environmental exceedances.

SCENTCZAR CORP. 213 Taylor Street Fredericksburg, VA 22405
Phone: PI: Topic#:	(540) 372-2004 Dr. Joseph E. Roehl NAVY 01-023 Selected for Award
Title:	Low-Cost Missile Environment Monitor utilizing a beam of radio frequency (RF) energy
Abstract:	This project will develop a monitoring system for the inside of Tomahawk missile canisters that can operate for an indefinite period exceeding five years with power provided by an external hand held reader using radio frequency (RF) energy. The hand held, battery operated reader will power the transponder inside the missile canister using RF energy to penetrate through its skin, charging a miniature storage capacitor that will operate a micro-power data acquisition system. The sensors will be passive devices only requiring power during readout. Our entire system of transponder and sensors will be easily installed in new or existing canisters without tools because it will be packaged in miniature modules with adhesive backings. All the sailor need do is remove the protective layer on the back of each package and press fit the module to the inside skin of the canister. Phase I will demonstrate the concept in the laboratory with breadboard sensors, the RF link, and a simple breadboard reader. Phase II will engineer an entire system which, in addition to working for Tomahawk missile canisters, will be easily adaptable to a wide variety of commercial applications.System will have wide application in grocery retailing, military logistics, and agriculture, where perishable items must be checked for spoilage without breaking open a package.

LAMBDA RESEARCH 5521 Fair Lane Cincinnati, OH 45227
Phone: PI: Topic#:	(513) 561-0883 Mr. Paul Prevey NAVY 01-024 Selected for Award
Title:	Innovative Gas Turbine Engine Propulsion
Abstract:	Low Plasticity Burnishing (LPB) has been shown to provide twice the HCF strength of shot peening, and four times the strength after FOD in Ti-6Al-4V and IN718 laboratory specimens exposed to turbine engine temperatures. The deep compressive layer produced by LPB is comparable to laser shock peening (LSP), and can fully arrest the growth of 0.020 in. deep fatigue cracks. LPB offers higher speed, lower cost, and better surface finish than LSP, and is performed on conventional CNC machine tools in a manufacturing or engine overhaul shop environment. The feasibility of applying LPB to compressor blades critical to the NAVAIR IHPTET and VAATE programs to improve damage tolerance and HCF life will be established in Phase I. LPB processing parameters and control software will be developed for following the complex surface of a compressor blade using existing tooling and 4-axis LPB facility. The HCF life and damage tolerance of LPB processed blades will be compared to the current practice of shot peening. Thorough documentation of HCF performance of LPB processed blades and development of an automated production LPB facility for blade rework will be undertaken in Phase II. The anticipated benefit of the proposed effort to NAVAIR is substantial reduction in the total cost of aircraft ownership and improved fleet readiness. LPB blade processing will improve engine HCF life and FOD tolerance, resulting in reduced costs of both replacement parts and maintenance. Increased damage tolerance will reduce required inspection time for further man-hour savings and increased on-wing time. The initial cost savings for the T56-A-427 compressor alone are estimated at $3.6M annually. Current military expenditures of $2B annually to address fatigue of aging aircraft and legacy engines provide the immediate market for LPB and potential savings to the DoD. Commercialization will, therefore, begin with NAVAIR overhaul and then expand to other military aviation applications. LPB is well positioned for commercialization due to low costs of operation and capitalization relative to laser shock peening(LSP), and improved depth and stability of the compressive layer produced by LPB relative to shot peening. LPB can be applied easily during manufacturing operations with conventional CNC tools at engine overhaul centers for much less than new blade costs. Demand for improved HCF performance and cost reduction from military owner-operators will lead to LPB processing of new blades and other critical rotating parts during manufacturing. Military applications will be followed in the commercial aviation sector, driven by improved HCF performance and cost reduction. Potential secondary commercial opportunities for LPB to improve HCF performance in the aerospace, automotive, and power generation turbine industries are vast, and will follow the initial military applications over a period of several years.

MAGCANICA, INC. 6723 Draper Avenue La Jolla, CA 92037
Phone: PI: Topic#:	(413) 442-1010 Mr. Ivan J. Garshelis NAVY 01-024 Selected for Award
Title:	Innovative Gas Turbine Engine Propulsion
Abstract:	Output shaft torque is a very useful parameter for health and usage monitoring, as well as electronic control, of turboshaft engines. Magnetoelastic polarized band technology is a novel method of torque sensing that provides a wireless signal while maintaining superior torsional stiffness, low mass, and packaging flexibility. Although this technology has been successfully proven in many automotive and industrial applications, its use to date has been limited to average torque measurement and niche production volumes. The objective of this project is to prove the feasibility of a magnetoelastic non-contact torque sensor for turboshaft and turboprop engine applications, with the specific goal of achieving a repeatable signal having large bandwidth from actual measurements on an engine output shaft. This test program is intended to demonstrate enhanced performance as compared with existing torque sensor systems, which more often than not present a heavy compromise among the desired resolution, bandwidth, and packaging. The significant weight and cost reductions, and long-term rotorcraft safety enhancements that can be achieved by the U.S. Navy through this new torquemeter make it well worth evaluating. This initial proveout is intended to provide the basis for a Phase II project to commercialize the technology for various military and commercial gas turbine engine applications.Torque is one of the most fundamental parameters used to analyze and control the performance of rotating machinery. Although all gas turbine engines generate mechanical torque at certain individual stages, turboshaft (and turboprop) engines are particularly well-suited for analysis of their system performance through torque monitoring due to the fact that they provide mechanical power through an output shaft. By demonstrating the feasibility, in hardware, of a magnetoelastic non-contact torque sensor for gas turbine engine output shafts that provides a high bandwidth signal, the following benefits are anticipated:  Far greater flexibility in packaging layout of the engine output shaft assembly  Improved torsional stiffness and output signal resolution with respect to existing strain gauge and phase shift torque sensors  Elimination of compliant torsion bar used in existing phase shift torque sensors, with a consequent weight and cost reduction  Lower torque sensor system and output shaft assembly physical length and mass  Improved ability to detect, and eventually prevent, potentially hazardous engine transient events such as flutter, surge, and stall  Improved HUMS capability during engine operation  Improved controllability of engine torque balancing in dual engine configurations  Enhanced capability for diagnostics in helicopter flight testing programs, especially airframe-engine matching and drive system dynamics The commercial implications of a successful high bandwidth torque sensor development program are significant. Truly non-contact, robust, accurate torque measurement for a variety of vehicle and industrial applications has been an elusive goal for many years. The advent of magnetoelastic polarized band technology, in combination with recent improvements in magnetic field sensor technology, suggest the strong possibility that at last reliable torque measurement, including that of transient events, is a real prospect for machine designers across many fields. Such a development could be put to use successfully in such varied applications as automotive engine control for reduced emissions, power control of helicopter engines and rotors, and tool condition monitoring in CNC machining centers. Due to the fact that there are literally millions if not billions of rotating shafts in the field that could benefit from integrated torque sensing, the ramifications of a successful program for U.S. military and industrial applications are exceptionally broad indeed.

MENON & ASSOC., INC. 12282 Libelle Ct. San Diego, CA 92131
Phone: PI: Topic#:	(858) 549-8886 Dr. Suresh M. Menon NAVY 01-026 Awarded: 07MAR01
Title:	Detection of foreign materials in prepregs
Abstract:	Fiber-reinforced polymer prepreg materials are supplied in the form of tape, tow, fabric, etc. During the cutting and lay-up processes, some of the backing material (release film) remains on the material. Composite parts manufactured using such prepreg materials can fail since the backing material prevents a good bond between individual plies. Menon and Associates proposes to demonstrate a magnetic resonance (MR) system to detect the backing material. MR principle is based on exciting the hydrogen atoms inside the material being inspected. Depending on the state of hydrogen we receive a unique signal. For example, the resin used inside the prepreg and the polyethylene or paper backing material have hydrogen atoms. However, the state of the hydrogen atoms in these two are different. We have a hand-held MR probe that can measure relaxation times of the hydrogen atoms in prepreg materials. This will detect any remaining backing material. In addition, if the backing material is aluminum, the MR field gets distorted and this also gives a good response. Using MR (similar to MRI in medical imaging) we can potentially measure wrinkles and voids at different depths by monitoring drastic variations in the signal from the hydrogen atoms from inside the composite. The capability of the proposed MR sensor for early flaw detection will result in a) improved fabrication and thus capability, b) increased life-time of the composite structure, and c) increased cost effectiveness. The commercialization potential is not limited to military uses but also includes civilian applications. Examples are the civilian aerospace industry, the automobile industry and sports industry.

THERMAL WAVE IMAGING, INC. 845 Livernois Street Ferndale, MI 48220
Phone: PI: Topic#:	(248) 414-3730 Dr. Steven M. Shepard NAVY 01-026 Awarded: 07MAR01
Title:	Enhanced Scanning Thermography for Large Scale Composite NDE
Abstract:	The increased use of composite materials in the manufacture of structural aircraft components such as the V-22 tiltrotor requires that Nondestructive Evaluation is performed frequently in the early stages of the fabrication process. Although Pulsed Thermography has been demonstrated to be an effective tool for many composite NDE applications, it lacks the speed and low cycle time required for frequent inspection during manufacturing. We have proposed a new approach to composite NDE, Enhanced Scanning Thermography, that provides the advantages offered by pulsed Thermography in a continuous scanning system that is ideal for the large, complex composite structures. The system will inspect parts while they are in the tooling at each debulk cycle, and provide fast, automated identification and measurement of defects such as wrinkles, voids or tape inclusions without operator input or intervention.Our proposal was formulated based on input from current and prospective customers in Government and private aerospace manufacturing, service, and R&D, including NASA, commercial airline, and military NDE personnel. We found that several major aerospace customers (Boeing, GKN Westland, Lockheed-Martin) were still using very crude scanning systems, simply because the systems matched the geometry of the parts they were inspecting. These customers indicated a high degree of interest in a scanning system that would incorporate the advanced features of the pulsed systems that they were using on other applications. Although the proposal has focused primarily on aerospace applications, significant market opportunities exist in the automotive and energy industries. The growing use of composites in automotive manufacturing and is presenting new QA and NDE challenges to the industry. TWI has been a pioneer in applying Pulsed Thermographic solutions to automotive applications, and has worked with Ford, General Motors, Chrysler, Nissan and numerous Tier 1 suppliers. The automotive market is distinctly different than the aerospace market, primarily because of the high volume requirements and the importance of autonomous, on-line systems. TWI has recognized and responded to these needs, will build on our experience in the automotive industry in marketing the scanning system."

POLYSPEC, L.P. 6614 Gant Road Houston, TX 77066
Phone: PI: Topic#:	(281) 397-0033 Mr. Paul H. Anderson NAVY 01-027 Awarded: 20FEB01
Title:	Sprayable Polysulfide Elastomeric Development
Abstract:	This project will develop a polysulfide based coating system that can be spray applied to marginally sound coatings that are coating steel substrates. The coating will be high solids, preferrably 100% solids, to minimize its environmental impact due to VOCs. The coating will have a low cure stress to aid in the adhesion. The adhesion of the coating system will be such that it will be able to wet out most common coatings already in use by the Navy.The coating will be able to adhere to most coatings used on Navy structures. The cure stress will be very low minimizing the chance of lifting a marginally sound coating system previously installed on the steel. The finalized system will expand our product line to include a process that our customer base is looking for.

UTILITY DEVELOPMENT CORP. 112 Naylon Avenue Livingston, NJ 07039
Phone: PI: Topic#:	(973) 994-4334 Mr. Harry s. Katz NAVY 01-028 Awarded: 20FEB01
Title:	Flexible Marking Paint for Asphaltic Airfield Pavements
Abstract:	Our main objective will be to investigate and develop flexible, abrasion resistant, environmentally compliant, waterborne acrylic marking paint for use on asphaltic airfield pavements. The developed paint will have reduced shrinkage upon cure and better adhesion to asphalt surface than currently used paint. The improved paint will have good flow and wetting to provide durability and excellent physical properties that will prevent deficiencies such as curling and cracking when applied on new paved surfaces. UDC will prove the feasibility and potential advantages of the new environmentally safe marking paint during this Phase I program. The developed materials will be tested in accordance with industry standards and ASTM methods. The tests will include elongation, tensile strength, residual cure stress, adhesion to asphaltic concrete, and abrasion resistance. At the end of Phase I, we will provide a report with results and conclusions, and a Phase II plan, schedule and cost estimate. This program will provide a flexible, abrasion resistant, environmentally compliant, marking paint for use on asphaltic airfield pavements. These marking paints will be directly transferable to all airfields with asphaltic pavements. This paint will also be used to mark municipal roads and parking structures.

UTILITY DEVELOPMENT CORP. 112 Naylon Avenue Livingston, NJ 07039
Phone: PI: Topic#:	(973) 994-4334 Mr. Harry S. Katz NAVY 01-029 Awarded: 20FEB01
Title:	High Adhesion Marking Paint for Portland Cement Concrete
Abstract:	Our main objective will be to investigate and develop flexible, abrasion resistant, environmentally compliant, waterborne acrylic marking paint for use on Portland Concrete Cement airfield pavements. The developed paint will have reduced shrinkage upon cure and better adhesion to Portland cement surface concrete than currently used paints. The improved paint will have good flow and wetting to provide durability and excellent physical properties. UDC will prove the feasibility and potential advantages of the new environmentally safe marking paint during this Phase I program. The developed materials will be tested in accordance with industry standards and ASTM methods. The tests will include elongation, tensile strength, residual cure stress, adhesion to Portland Concrete Cement concrete, and abrasion resistant. The developed materials and processing will be demonstrated by spray coating and testing of small test samples. At the end of Phase I, we will provide a report with results and conclusions, and a Phase II plan, schedule and cost estimate. This program will provide a flexible, abrasion resistant, environmentally compliant, marking paint for use on Portland Concrete Cement airfield pavements. These marking paints will be directly transferable to all airfields with Portland Concrete Cement pavements. This paint will also be used to mark municipal roads and parking lots and concrete structures.

SIGMA TECHNOLOGIES INTL, INC. 10960 N. Stallard Place Tucson, AZ 85737
Phone: PI: Topic#:	(520) 575-8013 Dr. Ali Boufelfel NAVY 01-030 Awarded: 14APR01
Title:	High Temperature, High Energy Density Multilayer Power Capacitors
Abstract:	At this point in time, existing capacitors technologies fail to meet satisfactorily Navy application needs for parts that are able to deliver energy densities greater than 1 J/cc and that are able to operate in severe conditions such as high temperatures, high operating voltages, and high currents. As a solution to this problem, Sigma proposes to develop a unique multilayer capacitor architecture to produce parts that are projected to deliver energy densities over 10 J/cc. These parts will be rugged enough to withstand the harsh conditions. In the phase I program, we propose to design and fabricate high voltage, high current, high temperature capacitors, with an energy density in the range of 10-20J/cc, based on existing and proven capacitor technology. The new capacitor design will based on Sigma's new nanocomposite patented technology that allows the production of polymer/inorganic multilayer capacitors that have improved self healing characteristics, higher breakdown strength, lower dielectric absorption and superior thermal and mechanical properties which result in higher current carrying ability. In the Phase II program, specific DOD applications will be addressed and capacitors will be produced and delivered for field testingThe new generation high energy density capacitors will serve a multitude of critical high power defense and commercial applications which may include motor controllers, inverters, power conversion, advanced linear motor, implantable defibrillators, pulsed lasers, electromagnetic catapults, high energy switches, radar modulators, isotope separation lasers, directed energy weapons, countermeasure pulse generators and other applications in the power electronics industry

TRS CERAMICS, INC. 2820 East College Avenue State College, PA 16801
Phone: PI: Topic#:	(814) 238-7485 Dr. Ming-Jen Pan NAVY 01-030 Awarded: 24APR01
Title:	High Dielectric Constant Polymer for Power Electronic Applications
Abstract:	Recently it was discovered that a relaxor ferroelectric copolymer consisting of poly(vinylidene flouride - trifluoroethylene) (PVDF-TrFE) exhibits a dielectric constant >60, more than 20 times the values of existing polymer film capacitors. In this SBIR program, TRS Ceramis and its subsidiary Centre Capacitor will demonstrate the feasibility of using this materials for compact, high volumetric efficiency, and low cost capacitors. This technology will bridge the gap between low ESR capacitors made with linear polymer, dielectric ceramics, and ferroelectric ceramics and high capacitance valued components such as electrolytics and ultracapacitors. In Phase I, commercially available polymer film will be processed to determine the optimum irradiation and film annealing conditions. The effect of electrode material (metallization)will also be studied to determine if self-healing electrode technology can be applied to this material. Prototype capacitors will be constructed by lamination techniques and the results will be used for pilot production in Phase II. The overall goal is to meet or exceed the DOD energy density requirement for DC bus capacitors.We anticipate relaxor PVDF-TrFE to be a breakthrough in capacitor technology leading to high volumetric efficiency components applicable to a broad range of markets. Besides military applications, PVDF-TrFE capacitors are expected to find wide use for implantable defibrillators, industrial motor drives, and electric vehicles.

BROADATA COMMUNICATIONS, INC. 2545 W. 237th Street, Suite K Torrance, CA 90505
Phone: PI: Topic#:	(310) 530-1416 Mr. Ling Sha NAVY 01-031 Awarded: 09APR01
Title:	Combined Direct Digital Synthesis, Predistortion and Efficiency Enhancement RI Power Amplifier
Abstract:	Broadata Communications, Inc. (BCI) proposes to development a novel Direct Digital Synthesizer (DDS) for high power radio frequency (RF) amplifiers. The development of this DDS is in response to the Navy's requirement for the development of a technique to pre-distort the signal fed to a high power RF amplifier in such a manner as to reduce distortion components to a point lower than -40dBc. This technology will combine digital synthesis and digital pre-distortion with efficiency enhancement to boost RF power amplifier efficiency and, at the same time, reduce cross modulation distortion often associated with higher efficiency power amplifiers. This device will be fabricated using the latest available, off-the-shelf commercial technology. It will be suitable for high power and high efficiency base station applications. Phase I will focus on hardware architecture design and algorithm simulation. In Phase II, a RF power amplifier, driven by the DDS with pre-distortion compensation, will be built to demonstrate the feasibility of the systems.The proposed DDS power amplifier approach is applicable to both, military and commercial markets. High efficiency power amplifier translates into lower battery weight or longer usage and lower costs. Together with low distortion generated by DDS with predistortion for today's highly complex and stringent modulation schemes, the proposed technology is a win-win solution for the wireless communication industry.

LINEARIZER TECHNOLOGY, INC. 3 Nami Lane, Unit C-9 Hamilton, NJ 08619
Phone: PI: Topic#:	(609) 584-8424 Mr. Roger Dorval NAVY 01-031 Selected for Award
Title:	Digital Compensation for Distortion
Abstract:	The development of a digital signal synthesizer with integrated predistortion linearization (DSS/PDL) is proposed. The DSS/PDL will generate complex waveforms and predistort these waveforms so as to compensate for the distortion of high power amplifiers (HPAs). All signal generation and processing will be done digitally. The use of digital processing for the predistortion (PD) allows precise complex transfer characteristics to be more easily generated. It also allows greater flexibility in generating and modifying these responses. Linearizer Technology, Inc. (LTI) will use its extensive experience in the design and manufacture of linearizers to develop a new class of digital distortion equalizers that offer superior performance, are faster and more efficient than earlier designs, and that are commercially viable. A novel architecture will be employed to overcome stability problems and allow a wider dynamic bandwidth than previously possible. Linearizers are essential in systems carrying bandwidth efficient modulated (BEM), high data rate digital signals. The largest part of LTI's business is providing linearizers to manufacturers of HPAs for satellite earth stations. Linearization is also of great value to the wireless telephone and personal communication industry. The implementation of digital techniques will allow LTI to produce linearizers with greater performance at a lower cost.LTI specializes in the solution of problems involving all aspects of non-linearity in communications systems. Although LTI provides both manufacturing and consulting services, LTI's principal business is the production of linearizers for microwave power amplifiers. LTI now makes more than ten standard linearizer models covering the L,S,C,X,Ku,K and Ka bands, designed specifically for satellite ground station and terrestrial applications. In addition, LTI offers custom linearizer design services for frequencies from base-band through millimeter wave and above, and engineering consultation for all forms of distortion related problems. LTI Linearizers are in use in the US and throughout the world. Users include SSPA, TWTA and KPA manufacturers, satellite system operators, major teleports and satellite users. These customers have continually expressed a desire for linearizers that will provide increased linearity, greater operational bandwidth and do not require alignment. These are the features offered by the DSS/DPL to be developed by this proposal. The digital predistortion technology will be initially integrated into the design of our standard linearizer products and offered as an option. This option will be promoted in the same way other LTI products have successfully been promoted. A new line of high performance linearizers tailored to the cellular and personal communications market place will be developed. This market place has not been directly addressed by LTI because of the difficulties involved in producing linearizers with very high C/I performance. The development of multi-band linearizers will also be considered. Interest has been expressed in a single linearizer to cover the C,X and Ku-bands for tri-band TWTAs. Such multi-band performance has not been possible with a single PD generator, but with a digital PD it should be achievable. Other business opportunities are anticipated as word spreads of the capabilities of digital PD linearizers.

V CORP. TECHNOLOGIES, INC. 7042 Nighthawk Court Carlsbad, CA 92009
Phone: PI: Topic#:	(760) 931-1011 Dr. Scott R. Velazquez NAVY 01-031 Selected for Award
Title:	High-Resolution Digital Linearity Distortion Compensator
Abstract:	This Small Business Innovation Research Phase I project demonstrates a breakthrough approach to high-resolution linearity error compensation (LinComp) using computationally-efficient digital signal processing to reduce harmonic and intermodulation distortion in digital-to-analog converters (DACs), analog-to-digital converters (ADCs), sampling circuitry, and radio frequency amplifiers (or the combination of these devices in the complete RF chain) by at least 24 dB. This technology improves the dynamic range by at least four bits, enabling very accurate synthesis of data at high intermediate frequencies (IF) with very high sample rates (e.g., 18-bit dynamic range with 300 MHz sample rate or 12-bit dynamic range at GHz sample rates). The LinComp technology reduces the size, power, and cost of radar systems and RF transceivers by eliminating much of the RF electronics and reducing the digital signal processing requirements. The significant performance improvements afforded by this approach over traditional compensation techniques will be demonstrated in Phase I by implementing the digital processing in realtime FPGA hardware, demonstrating efficient auto-calibration routines, an testing the processor on a combination of devices in an RF chain. The auto-calibration routines will be built in FPGA hardware in the Phase I Option. V-Corp has confirmed the technical efficacy of the LinComp processing methodology by testing with state-of-the-art digital-to-analog and analog-to-digital converters. This compensation approach requires less hardware, provides much better dynamic range, and provides compensation over a wider bandwidth than competing linearity compensation methods (such as phase-plane compensation and dither). Very importantly, the LinComp processor will always exceed the state-of-the-art because it can easily be upgraded as new, more powerful DAC, ADC, and amplifier products become available. During Phase II, a compact LinComp DAC prototype will be developed with a high-speed waveform generator and RF electronics to enable high IF direct digital synthesis (DDS).The LinComp approach overcomes the critical D/A conversion bottleneck which limits performance of state-of-the-art radio frequency transceiver systems. Virtually any high-performance modern electronic system will benefit from the LinComp DAC. Significant applications include enhancement of radar systems, wideband universal RF transceivers, specialized test equipment, and medical imaging systems.

ALPHATECH, INC. 50 Mall Road Burlington, MA 01803
Phone: PI: Topic#:	(781) 273-3388 Dr. John J. Fox NAVY 01-032 Selected for Award
Title:	Multi-Source Sensor Simulation for Decision-Making Systems
Abstract:	ALPHATECH proposes to design, develop, and demonstrate an integrated multi-source sensor simulation (MS3). It will be built upon a software infrastructure specifically designed for the integration of legacy software components. ALPHATECH will exercise the proposed architecture by integrating several existing simulation components through a well defined process that will adapt them for architectural compliance. The simulation will feature the generation of sophisticated target motions, GMTI sensor reports, an integrated user interface, and(optionally) SIGINT sensor reports. The user interface will support the specification of the scenarios, control of the simulation parameters, and visualization of the results.The proposed technology will help provide the DoD a tool for developing and testing algorithms that process multi-source data. In addition, the proposed design will have commercial applicability to any system involving the simulation of heterogeneous networks of sensors

COGNITECH CORP. 1060 East 100 South, Suite 202 Salt Lake City, UT 84102
Phone: PI: Topic#:	(801) 322-0101 Dr. Jerome B. Soller NAVY 01-032 Selected for Award
Title:	Simulating Data for the Development of Decision-Making Systems
Abstract:	Sensor outputs form the foundation for decision support systems. Accurate models and simulations of these sensor outputs enables effective development, test, evaluation and use of decision support systems. Phase I focuses on chemical/biological detectors because their variability embodies cutting-edge problems in the field of sensors and detectors. Phase I will focus upon the requirements, specifications, design, and methodology for modeling and simulating the inputs to decision support systems from outputs of detection (sensor) systems, which transform input data sources and associated uncertainties. These uncertainties include meteorological fluctuations, intrinsic and extrinsic noise of detection system channels and components, computer precision errors, and external disturbances. Existing simulations will be evaluated for incorporation into the methodology. Phase I will develop an initial prototype simulation of decision support system inputs, based on the methodology and simplified sensor models and simulations for the emerging Navy Artemis and ion mobility spectrometer detection systems. The resulting methodology will be extensible to other sensors. Phase I option period will add a graphical user interface prototype, initial database, and perform verification and validation. Phase II will develop a fully functional software prototype, including support for synchronized time representations between simulations.The sensor simulation environment will have applications as a simulation environment used by sensor/instrument manufacturers, government program managers, chemical process industries, and the developers of decision support systems.

DYNAMICS TECHNOLOGY, INC. 21311 Hawthorne Blvd., Suite 300 Torrance, CA 90503
Phone: PI: Topic#:	(310) 543-5433 Mr. Randall Patton NAVY 01-032 Selected for Award
Title:	Non-Acoustic ASW Sensor Modeling & Decision Aids
Abstract:	Dynamics Technology, Inc. (DTI) will develop non-acoustic ASW (NAASW) sensor algorithms and software to provide simulated sensor data, measures of performance, and innovative displays to support the analysis and development of decision aids for submarine situation awareness/vulnerability and mission planning. The approach is based on adapting and extending the Navy-standard PC-FOM suite of NAASW sensor performance models, which encompasses a wide range of sensors/signatures, and leverages two decades of Navy R&D and validation against high-fidelity simulations and field data. PC-FOM sensor models are designed to run rapidly and to provide militarily useful measures of performance such as probability of detection, making it ideally suited to decision aids. In addition to sensor performance modeling, DTI will develop candidate processing algorithms and displays (e.g. vulnerability maps, route planners) for integration into existing or future mission planning tools. Phase I research will: 1) demonstrate the utility of existing PC-FOM models and identify/prioritize upgrades and additions, (2) define NAASW decision aid CONOPS and display concepts, (3) demonstrate sample algorithms for vulnerability displays, and (4) determine the detailed requirements for Phase II development of a prototype NAASW sensor model and decision aid. The proposed effort supports a current need for vulnerability assessment and mission planning tools to support submarine operations in littoral environments. There are identified user needs and transition to operational use by Special Forces (NAVSPECWARCOM), ONI (threat assessment), ASW forces (e.g. vs. foreign air-independent propulsion subs), and the Submarine Technology Program (N775).

OCEAN SENSOR SYSTEMS, INC. 3561 N.W. 97th Terrace Coral Springs, FL 33065
Phone: PI: Topic#:	(954) 796-6583 Dr. Ken Holappa NAVY 01-033 Selected for Award
Title:	Innovative Sensor Technologies for In-Situ Air and Ocean Sampling under Extreme Conditions
Abstract:	The objective of this proposal is to demonstrate the feasibility of measuring in-situ the parameters necessary for the calculation of heat and momentum flux at the air-sea interface under very calm to moderate sea conditions. The Micro-Buoy proposed here will provide an off the shelf solution for the measurement of the near surface fluxes at a cost low enough to permit multiple synoptic deployment. Multiple buoy deployments will enable a better understanding of the local variability on time and space scales of order of seconds and meters to days and kilometers. The Micro-Buoy is fitted with the eddy correlation heat and mass flux instrumentation. With this package the heat and momentum flux is found at both sides of the air-sea interface. Measurements within a distance less than the significant wave height are difficult due to imperfect coupling to the sea surface of the measurement platform. The Micro-Buoy will allow accurate, high-resolution measurement of temperature and velocity micro-structure to within fractions of a meter of the water surface. Once the Micro-Buoy technology is developed, custom sensor packages will also be possible in addition to a standard set of sensor packages through the implementation of a modular design strategy.The expected market for the Micro-Buoys is the scientific community including various governmental agencies, academic institutions and the offshore oil industry. All of these parties have an interest in low-cost accurate assessment of the ocean environment and the air-sea surface fluxes of heat and momentum.

ENGINEERING ACOUSTICS, INC. 933 Lewis Dr., Suite C Winter Park, FL 32789
Phone: PI: Topic#:	(407) 645-5444 Mr. Thomas H. Ensign NAVY 01-034 Selected for Award
Title:	Compact High-Power Electronic Components
Abstract:	This Phase I SBIR proposed the development of technology that will lead to smaller, lighter and more efficient power amplifiers for driving the highly reactive loads presented by active sonar transducers. Compared to other amplifier components, existing designs employ physically large, high weight magnetic components in the amplifier-transducer coupling interface. Proposed research will focus on two new and innovative circuit topologies that accomplish the required transducer image impedance transformation by novel means. The approaches have the potential to realize substantial amplifier size and weight reduction while maintaining high overall efficiency when driven by state-of-art Class D power modules. The final part of the investigation will consider a fusion of the two approaches that may have advantage, especially for low frequency applications where magnetic components greatly increase size and weight of the amplifier. Phase I option will involve the design and fabrication of prototype power amplifier circuitry to test the analysis developed in Phase I and verify the operation of each circuit approach.The proposed research provides an important means of reducing overall weight and size in power amplifiers used in active sonar systems. Results will apply to the immediate market for the space/weight/efficiency optimized power amplifiers aboard Navy surface, submarine and airborne ASW platforms; and autonomous acoustic source systems such for acoustic tomography, active Navy sonobuoys, acoustic countermeasures, LELFAS and ADLFP. Other applications for the resulting technology will be in spacecraft and aircraft systems, where the benefits of space/weight efficient products are obvious. Additional applications include power distribution and power amplifier systems, control actuator driver circuits and high power modulators for communications

GREEN MOUNTAIN RADIO RESEARCH CO. 50 Vermont Avenue Colchester, VT 05446
Phone: PI: Topic#:	(802) 655-9670 Dr. Frederick H. Raab NAVY 01-034 Selected for Award
Title:	Compact High-Power Electronic Components
Abstract:	This Phase-I SBIR program will investigate novel techniques for the efficient delivery of signal power to reactive loads such as are required in sonar systems. Class-D and class-S power amplifiers with very fast switching offer a theoretical efficiency of 100 percent. Maintaining high efficiency with a reactive load is achieved by very fast switching, achieved by a new type of complementary MOSFET. Bandwidth can be extended by a new minimum-rating filter that allows maximum bandwidth within a given set of power-amplifier voltage and current ratings. An electronically tuned output filter allows significant extension of the frequency range. Electronically tuned inductors and semiconductor capacitors currently under development for another application can be adapted for such filters. Commercial applications include not only sonar and high-power audio amplifiers, but also RF power systems including RF heating, antenna tuning, jamming, and magnetic-resonance imaging.

QORTEK, INC. 4121 Jacks Hollow Road Williamsport, PA 17702
Phone: PI: Topic#:	(570) 745-3555 Mr. John Staron NAVY 01-034 Selected for Award
Title:	Compact High-Power Electronic Components
Abstract:	This proposal is to advance switching power electronics technologies to enable a compact agile acoustic source for high time-bandwidth product variable depth sonar. The solution is based on proprietary concept of interlaced polydrive high-energy inverter that uses DSP microcontroller to implement the switching architecture functions. The converter section will utilize a new compact `soft switch" resonant design and the thermal solution uses new isothermal heat pipe technology as to enable efficient packaging. The system will be tolerant of poor power factor loads. The digital controller will be able to download accurate phasing information directly into the drive electronics at high-speeds essential to the integrity of the waveforms. This modular system remote programmable towed array technology will function at full operational efficiency with an inverter module failure and enables `at convenience' low-cost replacement.Immediate applications include the enabling the use of high efficiency power electronics for the controls and audio systems industries. QorTek will be partnering with Universal Voltronics for technology transition of the proposed power electronics into new commercial products and Lockheed-Martin for use in U.S. Navy sonar systems.

SATCON TECHNOLOGY CORP. 161 First Street Cambridge, MA 02142
Phone: PI: Topic#:	(410) 694-8054 Mr. William Hall NAVY 01-034 Selected for Award
Title:	Silicon Carbide Technology for a Hull Mounted Sonar System
Abstract:	The development of compact, light-weight power-electronics for driving underwater acoustic transducers has been the subject of research over the past 30 or more years. Improvements have occurred in parallel with advances in power electronic switching devices, most notably, the development of the silicon MOSFET, essential for the high-efficiency switching-amplifier technology widely used today. We are on the threshold of another advance in power-electronics, the advent of silicon-carbide semiconductor technology, which offers great improvement in semiconductor operating temperature and voltage ranges. Its higher temperature capability will enable greater packaging density and its higher voltage capability will provide a closer matching of the switching device voltage rating with the voltage requirements of typical transducers, leading to the possibility of size reduction in impedance matching components. We propose to research the application of silicon carbide technology to an example hull-mounted sonar system, the AN/SQS-53C (part of SQQ-89 system), and determine its beneficial impact on transducer, power-amplifier and overall system design.As a minimum, we expect an improvement in power-amplifier density due to the higher temperature capability of silicon carbide, a benefit particularly significant for pulsed-power applications such as the 53C, with its high peak-to-average power ratio. A major benefit is the possibility of eliminating the power-amplifier output transformer. This transformer weighs an estimated 3 pounds and occupies about one-third of the volume of the power amplifier. For a system of about 600 amplifiers, the weight savings would be on the order of 1800 pounds. We expect the high voltage, high frequency capability of silicon-carbide switching devices will be adequate for driving the transducer element directly, eliminating the need for the output transformer. If the transformer can be eliminated, a third benefit is the possibility of integrating the power amplifier with the transducer, offering the opportunity for another significant reduction in overall system size and weight.

ARETE ASSOC. P.O. Box 6024 Sherman Oaks, CA 91413
Phone: PI: Topic#:	(703) 413-0290 Dr. J. Zandy Williams NAVY 01-035 Selected for Award
Title:	A Low-Cost Airborne EO Oceanographic Measurement System
Abstract:	The goal of this SBIR proposal is to evaluate the feasibility of transferring technology developed by Arete Associates for a UAV surrogate payload, the Airborne Remote Optical Spotlight System (AROSS), to a system capable of being mounted on an aerial photography airplane. AROSS is a field-tested and robust electro-optical system producing time-series imagery with sufficient resolution and spatial coverage for Navy METOC requirements. The approximate cost of $2000 per hour to fly AROSS, while not expensive by military standards, restricts its non-warfare or commercial use and its participation in ongoing scientific research. The development of a system similar to AROSS, which can utilize commercial aircraft, would cost less to build and reduce operating cost by a factor of 5 to 10. The limitation of the new system will be a restriction in the viewing geometry resulting from using a downward looking viewport instead of a military-based turret. Arete proposes to assess the effects of the restricted viewing geometry, using AROSS data, and determine the engineering requirements to mount such a system on standard, commercial aircraft.The successful transfer of AROSS technology to a system capable of being mounted in a commercial aircraft will be an inexpensive oceanographic research asset. This asset will directly benefit the Navy wave modeling community who require wide-area measurements of METOC parameters, including directional wave spectra, in the littoral zone. The lower operating cost of the proposed system will be more in-line with the budgets of typical field experiments designed to enhance scientific understanding of coastal processes. Government agencies responsible for coastal waterways, such as USACE, and mapping, such as NIMA, represent potential customers who can utilize the low-cost rapid bathymetric and current survey capability of the proposed system.

GERBER SCIENTIFIC, INC. 1643 Benatana Way Reston, VA 20190
Phone: PI: Topic#:	(703) 742-9844 Dr. Hermann E. Gerber NAVY 01-035 Selected for Award
Title:	Miniature Infrared Transmissometer (MIT)
Abstract:	The goal of this Phase I effort is to find a practical optical and physical instrumentation geometry that will result in a miniature infrared transmissometer (MIT) capable of estimating in-situ and in real time the atmospheric extinction coefficient for aerosols with particles ranging in size from a fraction of a micron to tens of microns. The approach of this research is to investigate the wavelength scaling between light scattered by the particles in the visible spectrum and the aerosol infrared extinction coefficient in the two atmospheric windows as a function of potential MIT geometries. Such scaling was previously described in the literature, but has not yielded a practical and miniature atmospheric sensor for estimating infrared extinction. Innovative solutions for known problems with the wavelength-scaling method will be sought to make the MIT a practical wavelength-scaling instrument.There presently exists no practical method for real-time and in-situ measurements infrared aerosol transmission (extinction). An atmosheric sensor such as the MIT would benefit the operation of infrard optical systems.

PRAXIS, INC. 2200 Mill Road, 5th Floor Alexandria, VA 22314
Phone: PI: Topic#:	(202) 767-6022 Mr. Kenneth A. Cannon NAVY 01-035 Selected for Award
Title:	Optimization of an Ionospheric Imaging Instrument for Geosynchronous Orbit
Abstract:	Disturbances in the earth's ionosphere can affect systems that rely on trans-ionospheric RF propagation. Validated DoD needs for real-time monitoring of ionospheric weather are not being met by current remote sensing techniques. Our proposal supports development of an ionospheric imaging instrument capable of providing realtime information on a global basis about ionospheric irregularities to improve tactical operational responses supporting surveillance, navigation, communication, missile defense, and precision geolocation. This SBIR effort focuses on reducing the instrument's cost, mass, and volume to facilitate integration as a secondary payload on geosynchronous satellite platforms. Future deployments aboard these platforms will enable real-time global monitoring of ionospheric disturbances affecting both DoD and Civil Sector systems.A successful effort would lead to production of multiple ionospheric imaging instruments as part of a global multi-platform geosynchronous real-time imaging system for monitoring structures and tracking irregularities within the earth's ionosphere. The system would provide real-time information to systems affected by ionospheric disturbances leading to improved surveillance, navigation, communication, missile defense, and precision geolocation. Potential applications to private industry communication systems may also provide benefits.

PROSENSING 150 Fearing Street Amherst, MA 01002
Phone: PI: Topic#:	(413) 549-6920 Dr. Ivan PopStefanija NAVY 01-035 Selected for Award
Title:	Weather Radar Processor for Rapid Scanning Tactical Radars
Abstract:	This Phase I SBIR proposal describes a weather radar processor that will be used to add a weather surveillance mode to existing military radar systems. Existing tactical radars, such as the TPQ-37 and MPQ-64, are highly sensitive search and track radars whose basic operational parameters are ideally suited for weather surveillance applications. During Phase I, we plan to work with engineers from the radar manufacturer to design one or more weather surveillance modes for the TPQ-37 and MPQ-64. A custom radar signal processor will be designed to extract reflectivity and Doppler data from the analog output of the radars. This data will be merged with antenna scanning, time stamp and geo-location information to accurately display the output data in world coordinates. Recurring and non-recurring costs to modify the radars for weather surveillance applications will be determined. The pulse-to-pulse scanning agility of these radars makes them especially powerful tools for the study of rapidly developing convective weather systems that are poorly characterized by conventional PPI-scanning weather radars.Commercial applications include modification of existing and new TPQ-37 and MPQ-64 radars for tactical and civilian weather surveillance applications. The radar processor developed through this SBIR can be readily modified for use with other civilian weather radars.

WESTERN ENVIRONMENTAL TECHNOLOGY LAB 620 Applegate St., PO Box 518 Philomath, OR 97370
Phone: PI: Topic#:	(401) 783-1787 Dr. Michael S Twardowski NAVY 01-035 Selected for Award
Title:	Four-Dimensional (4-D) Atmospheric and Oceanographic Instrumentation: A Novel Dual Wavelength Optical Beam Attenuation Meter for Automated Underwater
Abstract:	The technical and commercial feasibility of developing a miniature dual wavelength optical beam attenuation meter for use with Automated Underwater Vehicle (AUV) systems such as the REMUS is evaluated. The meter will use a novel Scattering over Dual-Pathlengths (SDP) approach, where two measurements of light backscattering are made with identical angular weighting functions but over different pathlengths. Using a single source, beam attenuation is readily derived from the ratio of scattered fluxes measured by the detectors and the difference between the two pathlengths. A key issue to address in determining feasibility is the tradeoff between increasing resolution and decreasing signal return as a result of increasing pathlength differentials between the two scattering measurements. A second challenge will be determining how to minimize and account for any light that is scattered more than the single incident in the sample volume (intersection of detector field of view and source beam), but still makes it to the detector. The SDP approach is likely the key to solving the apparent paradox of making high resolution attenuation measurements over very long pathlengths with a compact sensor. The sensor will be low power, robust, and have the approximate dimensions and volume of a hockey puck.Beam attenuation is a key property in diver visibility and vulnerability models, lidar performance models, and in determining particle concentrations in natural waters. Currently there is no commercially available miniature sensor for measuring optical beam attenuation with high accuracy. Such sensors are needed for deployment on the new generation of sampling platforms such as AUVs, profiling/gliding floats (e.g., the ALACE floats), and long-term, unattended observing systems. In the near future, thousands of such sampling platforms will be built. Revenues for a compact, high accuracy attenuation sensor costing about $3000 per unit are expected to be about $1.5 million annually (500 units per year).

NAL RESEARCH CORP. 8708 Sudley Road Manassas, VA 20110
Phone: PI: Topic#:	(703) 392-5676 Dr. Ngoc Hoang NAVY 01-036 Selected for Award
Title:	Data Link System for In-Situ Ocean Observing Platforms
Abstract:	According to a report by the National Oceanographic Partnership Program (NOPP), knowledge of the ocean is demanded by many constituencies including climatologists, fishermen and fisheries managers, harbor pilots, coastal zone managers, Navy and Coast Guard commanders, Public Health Service officers, environmental protection professionals, commercial and recreational boat and ship operators, weather forecasters, and the offshore mining and oil industry. Many of these needs are being met by in-situ ocean observing platforms such as drifting surface buoys, moored buoys, floats, remotely operated vehicles and ships, just to name a few. For these platforms, the NOPP has placed a high priority on the development of technologies that disseminate data in a timely manner. A variety of commercially available low-Earth orbit (LEO) satellite systems produced by the private sectors are now in, or will soon achieve, operational status. They have the potential to meet NOPP's requirements including two-way communications, real-time data transmission, global coverage, high data rate and reduced costs. As a result, NAL Research proposes to design and build a data link system utilizing LEO satellites to collect environmental parameters from ocean observing platforms and to deliver them to users worldwide in real-time.Satellite data link system can be extremely useful in many applications. Ships, airplanes and trucks have relied on geostationary satellites to provide mobile satellite services for years. Now, LEO satellite data link system will soon make mobile satellite services available for individuals. Any type of transmission, internet connection, voice, fax, data or paging, will soon be able to reach its destination anywhere on the planet. The system will simplify communications for business professionals such as salespeople, field producers and reporters for television networks, construction engineers sending plan revisions, oil-company geologists uploading test results, just to name a few. People who live in thinly populated areas that will never be covered by regular cellular phone service, travelers, private pilots, yachtsmen and disaster relief teams will benefit from the LEO satellite-based data link system as well.

OMNET, INC. Box 1285, (21 North Central Avenue) Staunton, VA 24402
Phone: PI: Topic#:	(703) 588-1078 Dr. David Martin NAVY 01-036 Selected for Award
Title:	A System for the delivery of data from remote unattended platforms using a Low Earth Orbit Satellite (LEOS) system
Abstract:	Field observational programs coordinated under the Ocean.US program require a reliable, global coverage, cost-effective, and flexible method of returning data from remote platforms, including moorings, surface drifters, and ALACE and PALACE floats. The present methods of doing this have many disadvantages: high costs, excessive latency, limited bandwidth, and limited geographic coverage. The PI proposes an integrated system for the retrieval and delivery of data from remote-moored and drifting unmanned sites and platforms in the ocean, using the Iridium Low Earth Orbiting Satellite (LEOS) system as the data carrier. The project will be coordinated with the Ocean.US Office and Ocean.US participants. The system will include a remote data communications package, bulk purchases and management of Iridium airtime, a data download hub with an Internet gateway, two-way comm- unications capability, and itemized billing. In Phase I, the PI will work in close collaboration with the NOPP Ocean.US Office to develop a detailed design, determine the cost-effectiveness of the proposed system and compare it with existing and planned next generation systems. We will prepare a risk and cost-benefit analysis comparison. We will also survey the market, both within the US oceanographic community and beyond.The anticipated benefits to the ocean research and operational communities are the availability of a system for the retrieval of remote data from ocean platforms which: = Provides true global geographic coverage = Uses a small, lightweight, low-power remote unit = Includes platform location capability = Provides higher base bandwidth (10 kbits/sec) than currently-available systems = Allows for channel multiplexing to achieve higher effective bandwidths = Has a lower cost per kilobyte of data traffic than any currently-available system = Can transmit data in real-time = Allows two-way communications = Provides a central system for support, itemized billing, and carrier quality monitoring = Provides a mechanism for automatic real-time distribution of data via the Internet = Provides a web-based data management and display service The system will be cost effective for delivery of data from terrestrial sites as well as ocean platforms. It has many potential commercial applications, including data communications for: = Ocean drilling platforms = River monitoring stations = Vessels at sea and in port (e-mail and data) = Geologic (earthquake) monitoring sites = Hazardous waste monitoring sites = Railroad infrastructure monitors = High-value mobile cargo monitoring = ...and others The proposed system would have advantages over the systems presently used for these applications: = Low cost per kbyte = Higher bandwidth = A single protocol/procedure globally = Lower cost equipment = Global coverage = Real-time data delivery = Allows two-way communications = Central itemized billing for multiple sites

ATLANTEC ENTERPRISE SOLUTIONS, INC. 1419 Forest Drive, Suite 205 Annapolis, MD 21403
Phone: PI: Topic#:	(410) 990-1100 Dr. Thomas Koch NAVY 01-037 Selected for Award
Title:	Technology for Shipbuilding Affordability
Abstract:	The objective of the project is to demonstrate that practical, affordable, and reusable software components can be used to create an affordable, real-time production monitoring and control system for U.S. shipyards. Atlantec and National Steel and Shipbuildng will develop, test, and demonstrate two product prototypes: "Production Monitor" an application that integrates engineering, production, with planning and scheduling; and "Shop Floor Client," a computer work station located in production areas. "Shop Floor Client" will allow production workers to retrieve and edit on-line production information from an on-site computer. Production processes will also be visualized in a "geographical" view of shipyard facilities, showing an activity at the production location providing the actual work status by work resource. The Proposed products, "Production Monitor" and "Shop Floor Control" will support just-in-time practices, enhancing productivity and reducing costs in U.S. Shiyards. Interim product, product model information, production status, and work order information will be accessable anywhere at anytime in the enterprise. The products will enable shipyards to integrate concurrent operations with real-time production information. The products will be affordable, practical, and will be easy to use and implement.

INDUSTRIAL PLANNING TECHNOLOGY, INC. 4555 State Road 524 Cocoa, FL 32926
Phone: PI: Topic#:	(321) 427-4892 Dr. Patrick W. Rourke NAVY 01-037 Selected for Award
Title:	Automated Planning and Design for Producability and Maintainability
Abstract:	Ship construction represents one of the more challenging planning problems in industry today. The purpose of this proposal is to reduce ship construction and operation costs by making optimal use of available automated fabrication facilities and designing for maintainability. An efficient algorithm for solving this class of problem has been discovered. The feasibility of developing software tools for automatic assembly planning and detailing of ship structure and outfitting and automatic maintenance removal planning will be demonstrated, using this algorithm. The tools would automatically plan assemblies, determine joint locations in piping and seam locations in structure, layout piping in banks, and plan maintenance access. A working prototype will be developed to verify that acceptable levels of fidelity and performance can be achieved. These new innovative tools will use accurate models of shipbuilding fabrication processes and life cycle operations so that they generate optimal designs/plans for shop production. In addition to the construction cost and life cycle maintenance savings, use of these tools will enable a substantial reduction in planning man-hours. The intent is to develop software components to be integrated into existing commercial CAD/CAM and planning systems. New design and planning business practices using these tools will be outlined.Anticipated savings are $160 million per year in construction costs and $1 million per year in planning costs for U.S. shipyards and $16 million per year in reduced ship maintenance costs for ship owners. This assumes that 10% of piping fabrication work is moved from in-dock and in-module on-site fabrication to mechanized shop fabrication as a result of this project and that 5% of structural fabrication operations are moved from on-site fabrication to mechanized process lanes as a result of this project. A 5% reduction in ship maintenance costs is assumed through optimum design for maintenance.

KNOWLEDGE BASED SYSTEMS, INC. 1408 University Drive East College Station, TX 77840
Phone: PI: Topic#:	(979) 260-5274 Dr. Perakath Benjamin NAVY 01-037 Selected for Award
Title:	Material Identification and Procurement System (MIDAPS)
Abstract:	We propose to design, build, and deploy a Material Identification and Procurement System (MIDAPS). MIDAPS facilitates information-integrated synchronization of construction activities with materials management functions through a rapidly reconfigurable, centralized relational database management system. MIDAPS facilitates both new construction and ship repair jobs. The Phase I effort will define, design, and build a prototype MIDAPS. The Phase II effort will rapidly transition the innovation into an operational shipyard application. The most significant innovation of the MIDAPS concept is the development of a materials system that becomes a real time management decision tool rather than a quasi-static information statusing tool. MIDAPS benefits include (a) significant reductions in ship construction and repair cycle time and cost, and (b) substantial gains in ship throughput and capacity. The proposed open-architecture, model-based approach will produce accelerated and affordable deployment of the technology to the U.S. shipbuilding community.MIDAPS applications areas include Enterprise Resource Planning, Material Requirements Planning, Finite Capacity Scheduling, Material Planning and Control, and Production Planning and Control.

RLW, INC. 1346 South Atherton Street State College, PA 16801
Phone: PI: Topic#:	(814) 867-5122 Mr. Lewis Watt NAVY 01-037 Selected for Award
Title:	Technology for Shipbuilding Affordability
Abstract:	A well-designed integration of a machine's control system with a CBM system will reduce manufacturing costs, simplify maintenance, reduce risk of critical failures, and reduce life-cycle cost of the machinery. This Phase I proposal's goal is to demonstrate the commercial and technical merit and feasibility of a combined CBM and control system for diesel generator sets on the Caterpillar 3608 and 3616. This machinery is not now digitally controlled, nor is it equipped with a CBM system. Both generators are either currently in service or scheduled for service soon aboard Navy ships, and each will eventually feature an electronic fuel control system. Choosing to integrate the engine control and CBM systems before designing either system will significantly reduce design, development, and implementation costs of both compared to designing and building both systems separately and then integrating after the fact. For example, the two systems can share a substantial portion of the sensors and other elements that typically compose the separate systems, thus reducing the total number of parts required and systems costs. The work accomplished by successfully integrating the engine control and CBM systems will benefit these generator sets and other machinery throughout the Navy and in commercial applications. Note attached letter of support from Caterpillar.The benefits anticipated from this project fall into three categories: 1) The direct and near term benefits derived from cost savings in acquisition and maintenance of the 3600 series gen-sets. Savings result from avoiding the cost of separate CBM and control systems and from the reduced cost of maintenance compared with a periodic preventative philosophy of run-to-failure. 2) Lessons learned and system design accomplished on this project will translate readily to other ship machinery, both new and legacy, generating savings as described above. 3) Because of the R&D accomplished in the project has direct and immediate application outside the DoD, rapid commercialization is anticipated in 3600 series gen-sets, and on a wide array of other machines. Note attached letter of support from Caterpillar.

CLEVELAND MEDICAL DEVICES, INC. 11000 Cedar Avenue, Suite 130 Cleveland, OH 44106
Phone: PI: Topic#:	(216) 791-6720 Mr. Frederick J. Busch NAVY 01-038 Selected for Award
Title:	Cellular Wireless Sensor System for Aircraft Health Management
Abstract:	Modern wireless systems such as cellular are practical due to the integration of radio, processing, and semiconductor technologies, and as production volumes have grown, component prices have dropped. Reduced costs and well-developed design methods may now combine to provide software controlled and highly cost effective wireless monitoring. The development and production costs for this equipment are easily offset by reduced maintenance cost and staffing allowed to users of the system. For military aircraft maintenance applications equally important issues are improvements in mission effectiveness and capability that result from reduced down time, higher reliability and sortie generation rates, and improved safety. Use of the commercial Industrial, Scientific, and Medical bands for this system design allow commercial reuse, and thus provides lower cost and greater availability to military users. The system will be designed with a Time Division Multiple Access (TDMA) Automatic Repeat reQuest (ARQ) for high spectral efficiency and reliability. The MicroRadio and data acquisition technology base of Cleveland Medical Devices provides an ideal starting point for this program.Greater military aircraft mission effectiveness, crew safety, and simplified maintenance are the chief benefits of this program to the military. However, the methods developed here will be immediately applicable to civilian aircraft maintenance, particularly airliners and corporate aircraft, and also to myriad other civilian monitoring applications. Virtually any complex equipment for which expensive regular maintenance is required could benefit from this new technology. Health monitoring of humans and animals may prove to be an even larger market than industrial and military data acquisition.

LUNA INNOVATIONS, INC. 2851 Commerce Street Blacksburg, VA 24060
Phone: PI: Topic#:	(540) 961-4516 Mr. Robert Harman NAVY 01-038 Selected for Award
Title:	Wireless Sensors Systems for On-Board Aircraft Health Monitoring
Abstract:	Aircraft diagnostic and prognostic systems can enhance aircraft safety, reduce total costs of ownership, and increase asset availability. However, they require a great deal of integration with the platform. Wiring such a system into the aircraft makes up a large percentage of overall system complexity, cost, and weight. Wireless transducers have enormous potential to simplify new and retrofitted diagnostic/prognostic systems by eliminating currently required cabling and interconnects, enhancing robustness via redundancy, easing sensor placement, and reducing system weights. A wireless system also allows for flexibility in sensor placement to meet changing system needs and to aid in identifying, troubleshooting, and monitoring emerging fleet problems. Luna Innovations and its research partners will develop a wireless sensor system for on-board, real-time aircraft health monitoring. The development team will survey the aircraft application and determine candidate sensors and system architecture. The system will work under constraints such as long operational lifetime, low power, non-light-of-sight, high bandwidth and ease of integration. The developed system will consider flight qualification, sensor size, and will offer performance comparable to existing systems. Luna will leverage previous wireless sensor development efforts and commercial production capabilities to satisfy the immediate Navy requirements and bring the developed technology to near-term market. Luna Innovations anticipates large related markets in preventive maintenance systems and diagnostic instrumentation coupled with wireless transmission capability. Specific applications include shipboard, spacecraft, aircraft, and nuclear/conventional power plant health monitoring, transportation vehicle design and testing, and industrial rotating machine monitoring. The previous success in this area resulted in a spin-off company, dedicated to the production of wireless instrumentation systems for industrial rotating machine health monitoring utilizing off-the-shelf RF technology, and has over $1 million/year in revenue. Products resulting from this research will undergo immediate transition for introduction to the market.

BUSINESS PERFORMANCE GROUP, LLC 5301 Shilshole Ave. NW, #330 Seattle, WA 98107
Phone: PI: Topic#:	(206) 706-8075 Mr. H. Bruce Bongiorni NAVY 01-039 Selected for Award
Title:	Integrated Simulation-Based Design Environment
Abstract:	This proposal provides a solution to problems in using disparate integrated computer-based design tools to determine the performance of underwater weapon and vehicle concepts. The proposed system would consist of a suite of domain-specific engineering software applications that undersea weapon and vehicle engineers would access and operate via personal computers as thin-clients over a secure network. Critical to enabling this design environment is a middle layer of software that provides workflow management, messaging services, analysis integration, optimization, and data and model persistence. A presentation layer of software applications will be able to provide an immersive user interface to interactwith engineering applications. Such a system can be easily extended as new analysis applications become available and as the user community grows. The benefit of such a system has two components, reduction of total ownership cost, and improved quality of design. The reduction of cost comes from the fact that potential design conflicts have been resolved early in design, in such a way that optimizes not only the weapon or vehicle design, but also its manufacturability, and life cycle maintenance costs. The system acheives this benefit by encouraging product team members to utilize the best available design, manufacturing, and operation tools, as well as to communicate and negotiate frequently. The system benefits not only the design team, but also the application developers, by allowing easier updates of codes during the design cycle, and by providing an environment to test, validate, and benchmark new codes. To the undersea weapon and vehicle design community, the system provides a framework for the product development, access to all the necessary applications, and produces greater capability than the individual applications alone.

TRIDENT SYSTEMS, INC. 10201 Lee Highway, Suite 300 Fairfax, VA 22030
Phone: PI: Topic#:	(703) 691-7781 Mr. Michael Stoddard NAVY 01-039 Selected for Award
Title:	Integrated Simulation-Based Design Environment
Abstract:	With the increasing complexity and size of advanced system designs come increasing requirements for an integrated set of methods and tools to measure, evaluate and predict behavior and performance. An environment is needed that will allow the engineer to rapidly iterate through multiple design paths and options, while evaluating the capability and completeness at multiple levels of abstraction. An integrated distributed environment is needed for engineers that support their processes and tools. This environment must support design, visualization and analysis at varying levels of detail. These capabilities can only be realized through the incorporation of a framework consisting of an integrated set of tools sharing a central design data repository that has "plug-in" support for external tools and codes. Creation of a robust environment to support complex systems development includes several key elements: first, an extensible framework and for integrating tools for designing, simulating and visualizing various aspects of the design; second, a process for using the tools and integrating and sharing their data; and third, a formal schema for describing, capturing and interrelating the data used by the tools. This project will attempt to realize a prototype of such an environment for the design and optimization of undersea weapons and vehicles. Successful completion of this project will represent a significant advancement in the design and optimization of undersea weapons and vehicles decreasing the design time while improving the performance and overall quality of the systems produced. This environment will provide an open, ubiquitous, distributed environment that will not only integrate existing and future codes and tools but also provide configuration management, asynchronous integration, advanced analytical and visual capabilities, as well as a flexible scalable environment based on Trident's Interchange product.

SOFTWARE & ENGINEERING ASSOC. 1802 N. Carson Street, Suite 200 Carson City, NV 89701
Phone: PI: Topic#:	(775) 882-1966 Mr. Douglas E. Coats NAVY 01-040 Selected for Award
Title:	Modeling of Composite Solid Propellant Combustion
Abstract:	Chemical kinetics based solid propellant combustion predictive capabilities have developed to the point where it is possible to compute combustion properties of solid propellants. Specifically burning rates over a range of pressures and temperatures. This capability will reduce the time, effort, and cost in developing solid propellants for a variety of combustion devices from rockets to air bags.The ability to predict solid propellant combustion properties will reduce cost and effort in designing and formulating new propellants. The cost savings to industry and the government are potentially enormous since only likely propellant formulations will be progress to the mix, cure, and testing phase of the development cycle.

BARRON ASSOC., INC. 1160 Pepsi Place, Suite 300 Charlottesville, VA 22901
Phone: PI: Topic#:	(804) 973-1215 Dr. B. Eugene Parker, Jr. NAVY 01-041 Selected for Award
Title:	Prediction of Hyperbaric Oxygen Seizures Using Neural Networks
Abstract:	It is known that hyperbaric oxygen (HBO) exposure causes seizures in animals and humans, although the mechanism by which this occurs is still incompletely understood. Oxygen toxicity is a concern, for example, in certain types of military diving operations, as well in treating patients in clinical HBO chambers. At present, the most reliable physiological "marker" known to anticipate HBO-induced seizures is escape from cerebral vasoconstriction. To provide an "early warning" system for increased probability of HBO-induced seizures practicable for field and clinical use, non-invasive measurement parameters are needed. For example, hyperbaric hyperoxia is known to increase the parasympathetic influence in the regulation of the heart. Therefore, subtle changes that occur in cardiovascular parameters (e.g., heart-rate variability) prior to the onset of seizures may be exploitable markers. Barron Associates, Inc. will apply its neural network estimation and classification technology, in conjunction with various signal analysis and nonlinear dynamics pre-processing techniques, to identify predictive cardiovascular parameters and to relate such parameters to seizure onset time and/or the probability of seizure occurrence. Successful development of a methodology that can account for individual differences in HBO susceptibility will lead to improved safety in diving and clinical applications. The proposed neural network-based predictive modeling technology has strong potential for application/integration in the Lung Automatic Regenerator (LAR) V Oxygen Breathing Device used by Special Operations Forces breathing pure oxygen. HBO therapy is widely used for the medical treatment of decompression sickness (i.e., the "bends") and many severe medical conditions (e.g., chronic wounds, acute blood loss, anemia, carbon monoxide poisoning, tissue/bone damage from radiation, gangrene, smoke inhalation, crush injuries, decompression sickness, air or gas embolism, persistent fungal infections, cyanide poisoning, bone infection, skin flaps/grafts with poor blood supply, and cerebral palsy). Improved prediction of HBO toxicity will have a large impact in HBO treatment.

CREARE, INC. P.O. Box 71 Hanover, NH 03755
Phone: PI: Topic#:	(603) 643-3800 Mr. David B. Kynor NAVY 01-041 Selected for Award
Title:	Prediction of Hyperbaric Oxygen Toxicity
Abstract:	Military divers and medical patients undergoing hyperbaric oxygen (HBO) therapy may breathe pure oxygen. The elevated ambient pressure levels in these circumstances lead to high partial pressures of oxygen which can become toxic. The goal of this program is development of a Diver Warning System capable of monitoring environmental and physiological parameters and predicting impending seizures due to oxygen toxicity. During Phase I, we will review existing data and literature, implement several novel data processing algorithms, and determine which parameters are most predictive of impending seizures. During Phases II and III, the work will be extended to include additional hyperbaric testing and integration of the Diver Warning System into the LAR V Rebreather used by military divers.Successful completion of this project will increase the safety of military divers exposed to hyperbaric oxygen. The technology developed under this program may also benefit recreational scuba divers and medical patients undergoing hyperbaric oxygen therapy.

VAXIN, INC. 500 Beacon Parkway West Birmingham, AL 35209
Phone: PI: Topic#:	(205) 934-6979 Dr. Felix Siegel NAVY 01-042 Awarded: 26APR01
Title:	Needleless Topical Administration of Dengue DNA Vaccine
Abstract:	Dengue virus (DV) is a serious threat to people including military personal in endemic areas. So far no prophylactic vaccine is available. The aim of this study is to develop a DV vaccine patch. Transcutaneous vaccination by topical application of a patch requires a lower level of medical training, is economical, painless, safe, and effective in a number of animal models. The hypothesis is that the expression of pre-membrane and envelope proteins (preM/E) in the outer layer of the skin following inoculation of DNA vaccines can stimulate neutralizing antibodies against preM/E and thereby induce a protective immune response against DV infection. Cholera toxin has been used as adjuvant for transcutaneous vaccination. We have previously shown that an immune response can be elicited by topical application of a plasmid coupled to adenovirus and that GM-CSF can enhance the potency of transcutaneous vaccines. In these studies, we will evaluate cholera toxin as well as GM-CSF as potential adjuvant for a DNA-based transcutaneous vaccine against DV. We will also compare the protocols developed in this proposal to their counterparts using intramuscular injected DNA vaccines. The line of investigation proposed herein may allow the development of efficacious and safe vaccination protocols against DV infection.The transcutaneous DNA-based vaccine as proposed in these studies could arrive as the first prophylactic vaccine against dengue virus infection if its efficacy and safety should appear superior to other methods. People living in endemic areas, military personal deployed to the tropics and subtropics and travelers would greatly benefit from an effective dengue vaccine, particularly a dengue vaccine patch that can be administered simply and confers no pain.

EIC LABORATORIES, INC. 111 Downey Street Norwood, MA 02062
Phone: PI: Topic#:	(781) 769-9450 Dr. Job Bello NAVY 01-043 Selected for Award
Title:	Autonomous Solid Phase Microextraction for Explosives Detection and Identification
Abstract:	The overall goal of this project will be to develop an automated sampling and chemical analysis system that can be used for detecting trace concentration of explosives in marine environments. Such an analysis system can be integrated into a small autonomous underwater vehicle (AUV) and employed for the identification and mapping of unexploded ordnance in bodies of water. Phase I will involve the design and fabrication of a prototype pre-concentration sampling instrument based on solid-phase microextraction (SPME). The prototype sampling instrument will automate the steps involved in the SPME sampling (extraction and desorption) and will be designed so that it can be easily interfaced with existing analytical methods for detecting explosives. The proposed design will utilize miniaturized components to achieve a compact, rugged sampling system that can be easily integrated in AUVs.The development of an autonomous underwater sampling and chemical analysis system for explosives will be both beneficial to the military and commercial sectors. An underwater explosive analysis system will be particularly advantageous to the Navy because it will provide an advance warning to naval vessels of the presence of mines in the surrounding area. This is important because it will then allow naval personnel to perform appropriate countermeasure actions. In the commercial sector, the underwater explosive system will also be important for environmental monitoring applications as well as in law enforcement.

NOMADICS, INC. 1024 S. Innovation Way Stillwater, OK 74074
Phone: PI: Topic#:	(405) 372-9535 Mr. Colin Cumming NAVY 01-043 Selected for Award
Title:	Novel Sample Collection Method for Locating Seamines
Abstract:	Nomadics proposes to design and evaluate a fast, in-situ apparatus to sample nitroaromatic explosives in marine waters. The sampler will extract explosive compounds from plumes around seamines and unexploded ordnance (UXO). By following a plume to its source, an autonomous underwater vehicle, guided by the sensor, will be able to locate seamines and UXO. The design introduces two novel technologies to allow rapid detection of trace signature chemicals of seamines. The system uses an innovative method for rapid mass transport of analyte into the sampling chamber. The second innovation is the sensor platform, which uses Nomadics' proven Amplifying Fluorescent Polymer sensor. The sensor has been demonstrated to detect extremely low concentrations of vapor-phase TNT and recent studies substantiate its ability to detect TNT in a water matrix. During the Phase I effort, Nomadics will demonstrate the ability of the collection system to present detectable levels of analyte to the sensor. During the Phase I Option, Nomadics will focus on enhancements to the system to support the transition into full prototyping in Phase II and then commercialization.The proposed system provides a way of locating explosives underwater that can be applied to detecting seamines, locating submerged UXO, finding lost ordnance, etc. These applications can be used by defense units and search and recovery organizations. The novel sample collection system is complementary to a number of sensor technologies, including ion mass spectroscopy, and the sensor platform can be functionalized to detect other substances. Therefore, the proposed technological innovations can be applied to a large number of chemical sampling and analysis scenarios.

SUBCHEM SYSTEMS, INC. 665 North Main Road Jamestown, RI 02835
Phone: PI: Topic#:	(401) 874-6294 Dr. Alfred Hanson NAVY 01-043 Selected for Award
Title:	A COMPACT SUBMERSIBLE TRACE CHEMICAL ANALYZER FOR TRACKING PLUMES OF CHEMICAL EXPLOSIVES WITH AUTONOMOUS UNDERWATER VEHICLES
Abstract:	A small autonomous underwater vehicle (AUV), with appropriate chemical, acoustic and optical sensor systems, would be a useful tool for remote, automated tracking and mapping of underwater plumes of leaking organic chemical explosives and locating their source. Presently it is not possible to survey and track such underwater plumes because available AUV-deployable chemical analyzers do not have the required lower limits of detection and fast response times. The primary goal of this Phase I project is to demonstrate the feasibility of developing an autonomous Submersible Solvent Extraction Module (SubSEM) that utilizes integrated microfluidic circuits to continuously sample and preconcentrate (100X - 1000X) explosive organic chemicals (i.e. TNT, DNT) that may be present at ultra-trace concentration levels in marine waters. The design of the miniature sized SubSEM will enable coupling to comparatively sized submersible chemical detection systems. The resulting compact submersible chemical analyzer will be readily integrated into small AUVs. The envisioned submersible chemical analyzer would also have the analytical selectivity, sensitivity (sub part-per-trillion) and fast response times (seconds) that are required for underway tracking of plumes of chemical explosives and the detection and identification of unexploded ordnance in the marine environment. AUVs with integrated high-resolution chemical and physical sensor systems are clearly needed for rapid detection, classification and localization of mine-like objects and unexploded ordnance in shallow water operating environments. Similarly designed AUVs could also have substantial private-sector applications in marine waters including, environmental investigations of the hydrodynamics of riverine and sewage inputs, hypoxia, harmful algal blooms and chemical pollution events, and commercial aviation search and find missions. There are also numerous private sector applications for submersible chemical analyzers with the lower detection limits afforded by the envisioned SubSEM preconcentration module. Examples include environmental monitoring of industrial and municipal waste streams for compliance and in-line quality assurance monitoring in chemical and pharmaceutical processing plants.

THORLEAF RESEARCH, INC. 5552 Cathedral Oaks Road Santa Barbara, CA 93111
Phone: PI: Topic#:	(805) 692-4978 Dr. Paul M. Holland NAVY 01-043 Selected for Award
Title:	Underwater Sampling Inlet/Preconcentrator System for In Situ Chemical Measurements of UXO Contaminants in Seawater from AUVs
Abstract:	Thorleaf Research proposes to develop and and test a rugged underwater sampling inlet/preconcentrator (SIP) system for in situ chemical analysis of seawater samples from a small autonomous underwater vehicle (AUV). This addresses a key technology gap for in situ underwater sampling and preconcentration of such analytes, mainly how to acquire and pre-process trace level analytes from seawater while remaining within challenging mass, volume and power constraints. Although various miniature chemical detectors are under development for explosives, their potential for the identification of UXO in marine environments will not be realized without complementary developments in technology for underwater collection and pre-processing of samples. The proposed SIP system will be suitable for coupling to such detectors, isolating them from the pressure of seawater at the selected sampling depth, and providing for automated 100-1000x preconcentration of TNT and other UXO analytes. The goal of our proposed SBIR Phase I effort is to demonstrate feasibility for a miniaturized, low power sampling inlet/preconcentrator system for in situ chemical measurements of UXO contaminants in seawater from AUVs, to develop detailed designs for fabricating prototype instrumentation in Phase II, and to fabricate and test a SIP system breadboard in a Phase I Option.By following an inherently modular design approach in developing this sampling technology, it is anticipated that modifications will allow it to be adapted to meet needs for a variety of underwater chemical measurements. This is likely to include terrestrial uses, such as environmental monitoring of water quality and monitoring for hazardous materials. Our proposed SBIR effort to develop a miniaturized, low power, underwater sampling inlet/preconcentrator (SIP) system for in situ chemical analysis addresses these needs in an innovative way, and thus technical developments in the proposed program could have a significant commercial market impact.

LANGUAGE SYSTEMS, INC. 5959 Topanga Canyon Blvd., Suite 340 Woodland Hills, CA 91367
Phone: PI: Topic#:	(818) 703-5034 Dr. Christine A. Montgomery NAVY 01-044 Selected for Award
Title:	Device Independent Voice-To-Voice Language Translation Software
Abstract:	The proposed innovative development and demonstration of a pocketable voice-to-voice language translator is achievable because it uses LSI's current PC-based, speaker-independent, two-way voice-to-voice translation software as a foundation for the effort. The development will involve six technical tasks; the first four are planned for the initial Phase I effort, and the last two for a Phase I Option. Tasks 1 and 2 involve extension and enhancement of LSI's current voice translation software using VoiceXML and Java to provide platform independence and a capability for remote activation. Task 3 is dedicated to dialog development/extension for a selected military application, and 4 is a test of the software developed under Tasks 1-3. Task 5 is a proof of concept demonstration for the standalone capability, and 6 involves experimentation with cellular, PDA, and hybrid devices to determine the optimal platform for both local standalone and remote capabilities. Motorola, which has expressed interest in the project, can assist LSI in testing the remote translation software, and in evaluating platforms for local and remote capability. The commercialization strategy for this development will follow LSI's strategy for commercializing our current voice-to-voice translation software, originally ported to the PC environment under a previous DARPA/Air Force effort.The pocketable voice-to-voice translator will benefit LSI's current law enforcement clients, as well as medical and paramedic service providers, retail financial service providers (banks, loan companies, real estate companies, insurance companies), organizations with multinational operations, business travelers and tourists.

SPEECHGEAR, INC. 4005 280th Street West Northfield, MN 55057
Phone: PI: Topic#:	(507) 664-0974 Mr. Robert D. Palmquist NAVY 01-044 Selected for Award
Title:	Compadre: A Device Independent Voice-to-Voice Language Translator Software Solution
Abstract:	Compadre Mission Statement: "To develop and deploy language translation software that is device independent, supports bi-directional translation of multiple languages, produces text transcriptions of spoken conversations and supports translation of text extracted from digital images. This software shall run in both a reduced functionality standalone mode, and by wirelessly connecting to remote servers, a full-function mode. This software shall run on multiple pocketable platforms resulting in a mobile system that is low in cost, easy to use, robust in operation and comfortable to carry and/or wear." The object of this Phase I research effort is to investigate the scientific, technical and commercial merit and feasibility of the system described in the preceding mission statement. Specifically, the team will investigate design options, identify potential applications, and select the best option(s) to pursue in making the system a reality. Four technical areas will be investigated: potential pocketable computing platforms, the operator interface, text recognition software and language translation software. Prototype systems will be developed and demonstrated. The commercial feasibility of this design will also be investigated. By combining both the commercial and technical elements, a complete definition of successful software and system solutions for pocketable language translation devices will be achieved. Applications include all individuals who require multi-lingual capabilities. The mobile translator will benefit a wide range of individuals including military personnel, airport employees, border patrol and customs agents, police, fire fighters, retail clerks, bank tellers, delivery personnel, phone operators, tourists and any industry that sells, develops or manufactures products to/in global markets or employs individuals that do not speak the native language.

III-N TECHNOLOGY, INC. 2033 Plymouth Road Manhattan, KS 66, KS 66503
Phone: PI: Topic#:	(785) 770-7814 Dr. Hongxing Jiang NAVY 01-045 Selected for Award
Title:	UV/Blue III-Nitride Micro-Cavity Photonic Devices
Abstract:	The research proposed here is built on the recent successful fabrication of the first electrically-pumped III-nitride micro-size LED, micro-size LED arrays, and waveguides by the principal investigator's research group at Kansas State University. New physical phenomena and properties begin to dominate as the device size scale approaches the wavelength of the light they emit, transmit, and detect. In this realm, quantum nature of light dominates, enabling more efficient and fast devices. The micro-size lasers and LEDs allow the ability to create arrays of individually controllable pixels on a single chip. Potentially these micro-size light emitters can operate as large arrays or independently to communicate millions of messages (or images) at the same time. Such vast numbers of micro-lasers could be used to read, write or process two-dimensional images, and to speed the flow of information between memory and processing chips as well as between different computer boards. Micro-cavity lasers based on III-nitrides offer additional benefits including shorter emission wavelengths (higher optical storage density and resolution), the ability to operate at much higher voltages and power levels due to their mechanical hardness and larger band gaps, and high speed due to the intrinsically rapid radiative recombination rates. The objectives of this Phase I research are to further develop the III-nitride micro-cavity photonic device technologies and to demonstrate the feasibility for achieving electrical pumped microcavity lasers as well as the integration of miniaturized light emitters with waveguides.III-nitride microdisk and microring lasers and arrays developed here are not only useful in compact displays, but also useful as emitters for remote free space functions and in short distance optical communication and high resolution and high speed optical links. By combining millions of the laser beams of these micro-lasers together, one may also obtain extremely high power lasers with very small size and simple designing. When an array of III-nitride microcavities is reverse biased, it can be modified as a miniaturized UV detector array. Thus III-nitride microcavity photonic devices open many important applications such as optical communications, signal and image processing, optical interconnects, computing, enhanced energy conversion and storage, chemical- and biohazard substances and weapon detection and warning and medical. III-nitride LED technologies will pave the way for full color displays and mixing three primary colors to obtain white LEDs for general lighting. The P.I.s have already developed a novel LED architecture that utilizes microdisk cavity LEDs and can boast the emission efficiency by more than 60%. Finding methods for increasing LED efficiencies is a key step for many applications, including full color displays and general lighting. There is an enormous market interest in the area of general lighting based on LEDs.

SENSOR ELECTRONIC TECHNOLOGY, INC. 21 Cavalier Way Latham, NY 12110
Phone: PI: Topic#:	(518) 783-8936 Dr. Remis Gaska NAVY 01-045 Selected for Award
Title:	AlN-GaN-InN Based Blue/Ultraviolet Integrated Optoelectronic Devices and Circuits
Abstract:	We propose to develop and commercialize GaN-based blue and near UV light integrated optoelectronics technology for modulation, switching, and distribution of blue and near-UV light. This technology will include integrated optical waveguides, splitters, and electrooptical modulators integrated with LEDs and photodetectors. We will investigate waveguiding in thin GaN, AlN, AlGaN, and AlGaInN films grown by SET, Inc. on different substrates. We will evaluate light coupling using commercial LEDs and blue high-brightness LEDs fabricated by SET, Inc. We will explore the integration design of GaN and GaN/AlGaN photodetectors developed by SET, Inc. The initial modulator work will investigate and implement an acousto-optical modulator based on GaN technology. The technology evaluation will rely on modeling and simulation using our optoelectronic CAD tool - simulator called photonic AIM-SpiceBiological and chemical substance detection and identification is very important for medical, biological applications, as well as for chemical and automotive industry. Integrated blue optoelectronics sensors have promise for the development of cheap and reliable GaN-based sensor systems drastically reducing cost, improving reliability, and safety.

PROGENY SYSTEMS CORP. 8809 Sudley Road, Suite 101 Manassas, VA 20110
Phone: PI: Topic#:	(703) 368-6107 Mr. Ronald D. Ghen NAVY 01-046 Selected for Award
Title:	Sonar Stimulation for Virtual Targets in Netted, Tactical ASW Training on Legacy Submarines
Abstract:	The Battle Force Tactical Training (BFTT) Program is the most widely recognized Navy program for in port netted training. The operational fleet desires to achieve a Netted ASW Training capability for the submarine community during range operations. Through use of current underwater communication modem technologies, the submarine would be able to communicate in net-centric training situations thus creating a synthetic battlefield situation. Progeny Systems has technologies that allow us to propose innovative bandwidth utilization, data compression techniques, as well as other weapon simulator systems to support the development of a complete "virtual" battlefield operation. Our communication management and data compression techniques have been successfully demonstrated at CTF-12 during the Advanced Undersea Warfare Concept (AUSWC) system demonstration in August 2000. Our data compression techniques were specifically designed to provide battle group connectivity for the submarine using legacy 2400-baud communication links. Through the adaptation of these data compression, data prioritization and data extraction algorithms to the underwater communication modem technology, we will enable the submarine to participate in BFTT operations. By evaluating Internet-Gaming technologies, we propose to further enhance the submarines ability to participate in this limited connectivity environment thus providing a reliable, efficient connectivity Advanced Training Capability.Progeny Systems is in the unique role of defining and constructing the battle group connectivity infrastructure required to link the ASW systems from surface, sub, air, surveillance and shore-based systems for the AUSWC system. As such, the concept of acoustic modem one-way connectivity for the submarine could be used in non-secure operations during battle group operations. We believe by coupling BFTT ASW Training Goals with the operational ASW Battle Force Connectivity a military commercialization opportunity with ASN RD&A may be available to demonstrate additional objectives in Battle Force Connectivity.The results of this project also have application to both commercial and military systems. Initially, this product would be best applied to government agencies and DoD for fleet submarines. As such, initial customers are intended to be PMS401, PMS415, PMS425, PMS450 programs and NAVSEA 92L1. Since the research is targeted towards improving coordinated (via netted communications) ASW training, the resulting technologies from this topic could support training in complex-theater operations, net-centric war gaming, airborne surveillance, NAVAIR, and surveillance applications requiring multiple participant training operations. Potential commercial applications are bandwidth management tools for enhanced Internet gaming, training for coordinated search and rescue missions and ocean exploration. During the research cycle, we will be in constant contact with industry, military, and university experts in the related fields. This will also provide us with the opportunity to identify new methods for achieving high performance innovative communication applications using industry standard development environments.

METROLASER, INC. 18010 Skypark Circle, Suite 100 Irvine, CA 92614
Phone: PI: Topic#:	(949) 553-0688 Dr. Cecil F. Hess NAVY 01-047 Awarded: 09APR01
Title:	Fiber Optic System to Measure the Size Distribution and Concentration of Airborne Aerosols in Multiple Locations of a Sampling Inlet.
Abstract:	This proposal discusses the development of an aerosol size spectrometer based on an innovative fiber optic system that provides versatility and ruggedness. The system will be compact and flexible and will provide the capability of installing multiple optical probes in an airborne sampling inlet or duct. The fiber optic system will be capable of measuring the size distribution and concentration of airborne particles using well-established principles that are similar to those used by the externally mounted probes. Analytical and experimental studies will be conducted during Phase I to demonstrate the feasibility of measuring the required size range of 0.5 to 50 �m and to work in flows with velocities from 1 to 100 m/s.The particle sizing system proposed here would be of significant benefit to government and industry engaged in atmospheric particle sizing and pollution monitoring. Instruments presently produced by several manufacturers would derive great benefit from the compactness and multi-probe capability of the proposed system. In addition to the airborne application, potential users include industries and Government agencies interested in powder technology such as food, pulverized coal combustion, and sand blasting.

SPEC, INC. 5401 Western Ave., Suite B. Boulder, CO 80301
Phone: PI: Topic#:	(303) 449-1105 Dr. Paul Lawson NAVY 01-047 Awarded: 05APR01
Title:	Characterization of Aerosol Inlets and Ducts
Abstract:	Atmospheric aerosols have a strong potential impact on both global radiative forcing and the planetary hydrological cycle. Quantitative measurements of the particle size distribution and composition of aerosols are required to reliably predict the influence aerosols are having on global climate change. Quantitative assessment of aerosol composition (i.e., chemistry) currently requires that air be ingested in the cabin of a research aircraft, where losses in the inlets and tubing are unavoidable. Simple and reliable instrumentation is needed for quantifying particle losses in inlets and tubing. In Phase I, we will design, build and make laboratory tests of a prototype instrumentation system for reliably measuring particle size distribution in tubing just prior to entry into cabin instrumentation. The inlet/tubing characterization system will easily be transferable from station to station and will be totally compatible with measurements made by the FSSP-300 and FSSP-100, currently the most reliable instrument for measuring aerosol size distribution outside the aircraft. In Phase II we will build an airborne version of the new instrumentation system and make comparative measurements with an FSSP-300 mounted on the outside of a research aircraft. It is expected that the new device will eventually be low-cost and readily adaptable for application in all inlet/tubing systems and research aircraft. Aerosol measurements are becoming increasingly more important and it is expected that inlet calibration devices will be purchased by almost all of the groups using research aircraft. In addition to research aircraft, inlet calibration devices will be useful in ground based operations, including measurements of pollutants in urban atmospheres and effluents from stacks. The ground-based applications open an extremely large commercial market.

ALPHATECH, INC. 50 Mall Road Burlington, MA 01803
Phone: PI: Topic#:	(781) 273-3388 Dr. Eric Jones, Nikolaos Denis NAVY 01-048 Awarded: 01MAY01
Title:	A Knowledge-Based Indications and Warning Toolkit for Mixed-Initiative Information Warfare Analysis
Abstract:	Naval intelligence centers validate, correlate, and analyze information from various sources (cryptologic sensors, tactical airborne reconnaissance, units in contact with the enemy, etc.) to generate Indications and Warning (I&W) in support of friendly operations. Increasingly, naval intelligence centers are deployed in littoral regions around the world. The close proximity of littoral threats significantly decreases warning and reaction time for friendly forces, while anticipated reductions in shipboard manning and increases in the range and quantity of available sensor data further exacerbate workload for intelligence personnel. New information fusion technology is required to help intelligence analysts meet these challenges. Accordingly, we offer a mixed-initiative knowledge-based approach to multi-source intelligence analysis in which user-specified rules and scripts are employed to infer I&W from large volumes of sensor data. To ensure scalability, the proposed system operates in three stages: data transformation, trend identification, and script/plan recognition. Data transformation performs statistical analyses and generates potentially useful abstractions of sensor data. Trend identification monitors these abstractions for user-specified triggering events. Finally, the script/plan recognition step generates I&W by matching these triggers to user-specified scripts for operationally significant activities. The technology developed under this program will immediately benefit cryptanalysts at naval intelligence centers, but also has ready application to intrusion detection for defensive IW, and to multi-source intelligence analysis for DoD and law enforcement.

ARGON ENGINEERING ASSOC., INC. 12701 Fair Lakes Circle Fairfax, VA 22033
Phone: PI: Topic#:	(703) 322-0881 Dr. Robert L. Kellogg NAVY 01-048 Awarded: 01MAY01
Title:	Indications and Warning (I&W) Inference Engine for the Information Warfare (IW) Picture
Abstract:	There are many approaches to improving IW systems' ability to provide Indications and Warning (I&W) for the Information Warfare (IW) Picture. Traditional approaches have relied on rule based systems to infer the RF environment. But in the modern IW battlespace the rules may change too quickly to effectively write IW heuristics. This SBIR takes an innovative approach to deriving the IW Picture by investigating self-organizing algorithms to quickly classify and parse the RF environment in a high-order parametric space only available to the sensor itself. A number of algorithms have been tentatively identified as prospective candidates for investigation, including hard and soft Hebbian learning and neural-gas algorithms. It is expected that these algorithms have the potential to separate signals not only by their individual parameters (frequency, bandwidth, etc.), but also by important (and a priori unknown) joint parameters such as transmission timing, secondary signal follow on, and diffuse RF environmental changes. During Phase I, the self-organizing algorithms will be selected and put into a mathematical foundation suitable for inferencing using IW system high-order data sets. The algorithms will be coded (JAVA is the current language of choice for machine independence) and subjected to well controlled data sets with parameter vectors that match IW systems used in both the National and Tactical RF environment. The performance of the self-organizing algorithms will be evaluated and compared. It is anticipated that one or more algorithms will be recommended for further testing in a prototype system. Initially this software system will be demonstrated on the new generation of IW systems, such as those built on LIGHTHOUSE Technology. However, by using JAVA as machine independent code, the software can migrate to other generations of IW equipment. It is expected during Phase II that a successful IW Inferencing Engine will become a GCCS-M/CUB software segment. We envision multiple opportunities for commercializing the software products that are developed under this SBIR. The immediate opportunities for commercialization involve other government agencies that have similar problems with rapidly interpreting changes in the RF environment, whether to identify hostile threat or to recognize illicit communications. There are extensive applications in the telecommunication industry for monitoring and predicting traffic loads and managing predictable interference. Further, the same concepts of self-organization may be applied to other disciplines including weather prediction and stock-market forecasting.

TECHNOLOGY SERVICE CORP. 11400 West Olympic Blvd., Suite 300 Los Angeles, CA 90064
Phone: PI: Topic#:	(301) 565-2970 Mr. Henry Schmidt NAVY 01-049 Awarded: 01MAY01
Title:	Enhanced Data Rate Performance for VLF/LF
Abstract:	Fleet Submarine Broadcast System (FSBS) VLF/LF communications are severely bandwidth limited due to the high Q of the transmit antennas and the low frequency of the VLF/LF band. The existing communications modes were designed using Minimum Shift Key (MSK) waveform modulation built into analog modulation and demodulation equipment. Soon the very capable digital Submarine Low Frequency/Very Low Frequency VMEbus Receiver (SLVR) will be deployed throughout the submarine fleet, and the analog modulators will be replaced by digital modulators. Advanced modulation techniques such as partial response continuous phase modulation (CPM) at higher baud rates can now be considered for implementation in FSBS communications equipment. In addition, Low Density Parity Check Codes (LDPCC) that provide additional coverage performance through forward error correction (FEC) are already being used for FSBS communications and additional improvements in these codes have been identified. Finally, incremental improvements in current Range Extension Mode (REM) message data compression are also feasible. TSC proposes to investigate designs that incorporate a combination of advanced modulation techniques, adaptive data compression, and larger block size and higher code rate LDPCC for the band-limited VLF communication channel in order to increase the data rate of FSBS information transfer 2 to 5 times yet maintain good coverage range.This research will establish the compatibility and combined performance of partial response continuous phase modulation (CPM) used with Low Density Parity Check (LDPC) forward error correction codes and will establish the compatibility and combined performance of these with adaptive message data compression techniques. These results will lead the way for SPAWAR to incorporate these improvements as software modernization/upgrades into Navy VLF/LF transmit and receive terminals. In addition, these results may also be implemented in application-specific integrated circuits (ASICs) or software modules as data rate upgrades to HF, VHF or UHF narrowband communications modes.

GMA INDUSTRIES, INC. 20 Ridgely Avenue, Suite 301 Annapolis, MD 21401
Phone: PI: Topic#:	(410) 267-6600 Mr. Glenn Wright NAVY 01-050 Awarded: 01MAY01
Title:	Remote Data Set Manipulation and Fusion via Bandwidth-Independent Networks
Abstract:	The approached described within this proposal focuses on the identification and analysis of existing data sources and their targeted users, coupled with the development of a prototype client-server network and user application. The results from the data sources and user analysis will provide us with valuable data to be used for testing purposes during Phase I. Also, the information will give us a jump-start in developing the complete system during Phase II. The prototype network and application resulting from Phase I will demonstrate the capabilities of the client-server network. Results will demonstrate the ability for remote users, regardless of bandwidth limitations, to access, view, fuse, and manipulate data from multiple sources. Emphasis will be placed on the layout of the network, the necessary hardware, the development of a user application, and techniques to limit the amount of data that actually needs to be physically moved. A detailed description of how the network will be laid out will be presented, along with how the software will be developed to bring together the entire network.Anticipated benefits include order of magnitude improvement in data management capabilities of remote users restricted by low bandwidth communications channels. Commercial opportunities exist in providing access to data at locations, especially third-world countries, where the data communications infrastructure is rudimentary or non-existent and low-bandwidth satellite communications is the only option.

ACULIGHT CORP. 11805 North Creek Parkway S., Suite 113 Bothell, WA 98011
Phone: PI: Topic#:	(425) 482-1100 Dr. Dennis Lowenthal NAVY 01-051 Awarded: 01MAY01
Title:	Optical Powering Of Systems
Abstract:	Undersea, fiber optic, cable systems are currently either battery powered or powered from shore via a conductor that is part of the cable. For the former, large battery packs must be deployed wherever electronics are located along the system. For the latter, the conductor in the cable dominates system size and controls system cost. An alternative concept is to power the fiber optic cable system by sending laser power from the shore side of the cable that is tapped off at locations where electronics are located and converted to electrical power for powering the electronics. In Phase I Aculight will extend a breakthrough technology it has developed on DOD funding to demonstrate diffraction limited diode laser bar sources that can be coupled efficiently into single mode fibers at the multi Watt level. In addition, Aculight brings new manufacturing techniques, based on semiconductor fabrication, that will result in robust and long life power sources. This combination will provide an efficient and compact device for supplying optical power into a single mode fiber for optical-to-electrical converters. Our proposed Phase I work will demonstrate the feasibility of achieving the Navy specifications in laboratory experiments. This ambitious plan is possible because of closely related research accomplishments.Techniques that deliver optical power into a single mode fiber, or multi-mode fiber, have significant markets in DOD (illuminators, power into fibers, pumps for fiber lasers) and the commercial sector (telecommunications, marking, materials processing, sources for end pumping solid-state lasers, and medical diagnostics).

CRITICAL TECHNOLOGIES, INC. Suite 400 Technology Center, 1001 Broad Street Utica, NY 13501
Phone: PI: Topic#:	(315) 793-0248 Mr. George H. Palmer NAVY 01-052 Awarded: 01MAY01
Title:	Compressed Internet Protocol (IP) Data Via Geosynchronous Earth Orbit (GEO) Satellite Circuits
Abstract:	TCP/IP is the leading protocol used by networked applications the Navy requires to perform its mission. However, TCP/IP was designed for use in reliable, but possibly congested, wired networks, and thus does not support stealthy communication over intermittent and degraded wireless links as required by the submarine fleet. To enable IP-based applications in the submarine environment, CTI will investigate and define requirements for an integrated system, comprising enhanced Data Link and Transport layers, and an innovative Application Traffic Controller, that provide optimal SATCOM link utilization despite high/unstable Bit Error Rate, low bandwidth, long latency, and intermittent connection. For use under Low Probability of Detection / Intercept conditions, additional protocol enhancements will provide reliable transport of IP traffic to the submarine without acknowledgement. This system will operate over any intermittent and degraded wireless media such as HF, UHF LOS/SATCOM, and sonar data transmission, providing significant benefit to both Commercial mobile platforms and Naval mobile assets such as surface ships, aircraft, brown-water Navy, and special operation forces. The severely constrained radio communication environment of a submarine coming infrequently to periscope depth, with a small antenna rising barely above the waves from a rolling platform, confounded by anti-jam and LPI requirements, is a worst case for mobile wireless networking. Historically, the commercial wireless industry has not focussed on such harsh environments. Now, however, network operators and equipment manufacturers recognize a large and growing demand for reliable provision of multimedia services to highly mobile users with extremely small devices, despite severe multipath, fading, interference, spectrum crowding, etc. Solutions to this Navy problem should be directly cross-applicable to the consumer space.

OPTIMIZATION TECHNOLOGY, INC. 125 West Park Loop, Suite 201 Huntsville, AL 35806
Phone: PI: Topic#:	(256) 721-1288 Mr. Robert C. Cox NAVY 01-053 Awarded: 01JUN01
Title:	Runtime Evaluation and Prediction System (REPS)
Abstract:	OTI proposes to research and develop the Runtime Evaluation and Prediction System (REPS) technologies providing the advanced methodology, techniques and integrated tool suite required for the most effective utilization of existing simulation capabilities for real-time or near-real time course-of-action (COA) analysis. In rapidly changing environments, maximum benefit from simulation technologies can be achieved only if the simulation users can reliably predict the time delay from the beginning of a simulation-based analysis effort until the results become available. In addition, REPS capabilities will greatly improve the potential benefit from simulation through significant improvement of productivity from the available resources, including both computing resources and human analyst resources. Significant productivity enhancements are expected from REPS as a consequence of better allocation of the limited human and machine resources to focus on those simulation scenarios that are likely to produce the required analysis results within the specified time constraints.As both DoD and commercial systems continually grow in size and complexity, simulation techniques are increasingly used to evaluate expected system behavior under a wide range of possible conditions. However, increasing size and complexity of the modeled systems also tends to rapidly increase the runtimes for the simulations and the application of simulations for course-of-action (COA) analysis requires that the simulation-based analysis results be available in time to impact the decision making process. Furthermore, it is frequently the case that the selection of simulation configuration parameters can have a very large impact on the runtime of a simulation experiment. REPS provides the additional automated tool support is necessary to reliably and accurately predict the runtime of a simulation model based on the configuration of models, model parameters, and the availability of simulation execution host machines. REPS research will greatly improve the ability to quickly and accurately predict the runtime for simulations employed for the purpose of course-of-action (COA) analysis. Specific benefits from improved predictive abilities include: 1) greater effectiveness of existing simulation based course-of-action (COA) analysis techniques; 2) more efficient utilization of scares human resources; 3) more efficient utilization of limited computing resources; 4) reduced frequency of analysis results that are not produced in time to be useful for decision making processes.

KERNCO, INC. 28 Harbor Street Danvers, MA 01923
Phone: PI: Topic#:	(978) 777-1956 Mr. Michael Delaney NAVY 01-054 Awarded: 01MAY01
Title:	Precise Time and Frequency for Navy Applications
Abstract:	As the reliance on the Global Positioning System (GPS) increases, so too does the risk to dependant systems caused by GPS signal outages or acquisition problems. Timing and synchronization systems, such as Navy operational sites, can benefit from a precision common time reference that offers atomic frequency standard stabilities without drift or total dependency on GPS receivers. Advanced atomic clock technology utilizing Coherent Population Trapping (CPT) as a basis can provide a compact, cost effective solution to the growing need to provide a coordinated knowledge of time while maintaining independence from the GPS system. NAVSSI and Link-16 terminals could be significantly upgraded upon the availability of reliable atomic clock performance in a package compatible with subject Navy hardware.The CPT clock technology has a wide range of applications outside of the military frequency and time area. A compact, low-power, low cost frequency/time standard would find a market in virtually every aspect of modern electronics including communications, test and measurement, computer networking and personal location and positioning devices.

SYNTONICS LLC 9520 Bendix Road, North Columbia, MD 21045
Phone: PI: Topic#:	(410) 480-7205 Mr. Glen E. Cameron NAVY 01-054 Awarded: 01MAY01
Title:	PICO - A Small, Intermediate-Term Precision Time and Frequency Source for NAVSSI and LINK-16 Terminals
Abstract:	Syntonics proposes to develop a precision time and frequency source with excellent intermediate-term timing stability (accuracy better than 1e-12 seconds over several hours), long life and high reliability. This intermediate-term precision time and frequency source will use a time scale generator based on an ensemble of small quartz oscillators. This product would give the Navy an inexpensive time and frequency standard with the precision necessary for the Navigation System Sensor Interface (NAVSSI) and Link-16 terminal, but with significantly higher reliability and longer service life that any solution using an atomic physics package.An inexpensive, highly reliable and long-lived time source with the signal purity and short-term (i.e., up to approximately 20 minutes) stability of a good quartz oscillator, and with the intermediate-term (i.e., 20 minutes to one day) stability of an atomic standard would have numerous commercial applications. Today's marketplace offers a variety of cesium- or rubidium-based frequency sources with good intermediate- and long-term time stability, but their short-term stability and phase noise performance is inferior to a precision quartz oscillator. Further, they are relatively expensive, unreliable and short-lived compared to quartz oscillators.

INTELLIGENT AUTOMATION, INC. 7519 Standish Place, Suite 200 Rockville, MD 20855
Phone: PI: Topic#:	(301) 590-3155 Dr. Leonard Haynes NAVY 01-055 Awarded: 30APR01
Title:	Information Warfare Sensor and Wireless Network Using TM-UWB
Abstract:	We propose to develop an information warfare sensor network based on Time-Modulated Ultra-Wideband radio. TM-UWB radio has several characteristics which make it ideal for low cost covert recovery of wideband data. The only signals transmitted by UWB radio are pulses generated pseudo-randomly in time. The Fourier transform of a perfect impulse is constant at all frequencies. The pulses we are currently using are � nanosecond in duration and the energy extends approximately from .5 to 4 gigahertz. The energy content in any conventional frequency band is far below the noise, making TM-UWB transmission very difficult to detect unless you know the specific pseudo-random sequence of the pulses. With TM-UWB there is no carrier frequency, there is no up conversion and no down conversion required, and the output stage is a single transistor which creates a binary pulse, all resulting in decreased radio size and complexity. The duty cycle of the pulses is approximately 1/500, resulting in low power consumption because 99.8% of the time, nothing is being transmitted. During phase I we will demonstrate UWB communication at 5 miles with at least two simultaneous channels. We will also evaluate several innovative system concepts related to the IW sensor network, including ad hoc network protocol and range measurement capability.While IW sensors do not represent a very large commercial market, the basic technology has very large commercial potential in health, telecommunication, manufacturing, and security industries. For example, in the health care industry, TM-UWB offers a single mechanism for wireless communication to and from mobile instruments, plus it offers the ability to track the position of each of those mobile assets.

PHYSICAL OPTICS CORP. Information Technologies Div., 20600 Gramercy Plac Torrance, CA 90501
Phone: PI: Topic#:	(310) 320-3088 Dr. Andrew Kostrzewski NAVY 01-055 Awarded: 02MAY01
Title:	Information-Technology-Enhanced Asymmetric Sensor Star (ITEASS) Wireless Network for Recovery of Wide-Band Data
Abstract:	Physical Optics Corporation (POC) proposes to design and develop an entirely new wireless network for recovery of wide-band sensor data. This network is based on the Information Technology-Enhanced Asymmetric Sensor Star (ITEASS) architecture, which consists of an asymmetric communication interface (CI) for both longer-distance (100 mile) BLOS (beyond-line-of-sight) communication between a relay and processing center and short-distance (5 mile) sensor wireless LAN (WLAN) with LPI and LPD. The proposed network has exceptionally high tolerance to multipath errors, necessary for sensors fielded in urban and littoral areas. System novelties include: low millisecond latency, essential to real-time interaction sensor control; PCMCIA sensor-specific communication interface; IT-superhigh compression encoding for wide-band sensor data; and spread-spectrum-code-division-multiplexing access (SSCDMA) software and hardware. The ITEASS will be modular to accommodate diverse sensors (TV, video, wide-band RF, radar imaging, sonar, acoustic, seismic, and EO/IR imagery). It will operate at 50 MHz for BLOS: TCDL, CDL, IDL; and ~1 GHz for the sensor LAN. The stand-alone system will cost only ~$100 per board, in spite of its supercomputer-class 8BOPS distributed processing power. It will be compact (2 in. x 3 in. PCB); low-power (~1 W); mass-producible; and designed for both required modes of operation: snap shots and streaming.Commercial applications include the rapidly growing world markets for cellular videophones (2.5G and 3G), video conferencing, IP-streaming video, and video surveillance, which together are expected to generate annual sales of $250 billion in the year 2002.

ORINCON CORP. 9363 Towne Centre Drive San Diego, CA 92121
Phone: PI: Topic#:	(703) 351-4440 Dr. Kevin Heaney NAVY 01-056 Awarded: 01MAY01
Title:	A Multisensor Approach to Covert Acoustic Calibration of Littoral Environments Using Sources of Opportunity
Abstract:	Submarine detection in the littoral environment is a very challenging problem. Acoustic propagation depends critically on complex oceanography and bottom sediment type. The difficulty lies in determining these quantities in a covert manner. We propose the development of a suite of algorithms that will fuse multiple platform data received from surface ships of opportunity to determine the environmental parameters required for ASW operations. The objective of this work is the development and evaluation of four algorithms (with increasing complexity and pay-off). The algorithms range from critical angle estimation from striation patterns to matched field geoacoustic inversions using simulated annealing. Each algorithm will be developed and evaluated using existing data. One available data set is from the ADS Fleet Exercise Test/SwellEx-99 conducted in 1999. This includes GPS records of ship tracks, environmental measurements for "truth" estimation, and data from ADS and several other acoustic arrays. The objective of Phase I is to validate the scientific approach to environmental characterization and to select appropriate algorithms for further development. In Phase II, a system concept will be developed for insertion into select ASW assets. Phase III will conclude with sea trials and system installation into one or more of the specified IUSS systems.Phase I of this research will lead to robust algorithms that determine the physical quantities of interest to current ASW platforms (beamformers, prediction models, noise models, etc.). These algorithms will be used to produce an automated rapid environmental calibration software suite for the ARCI-IUSS acoustic processing system. We envision this being used daily on a submarine in forward areas where geoacoustic/oceanographic sound speed databases are sparse, or for the ADS system where covert calibration is required. Given accurate geoacoustic parameters for an area and real-time surface ship locations, a real-time ambient noise model can be used to determine tactically relevant system performance.

B&B ENGINEERING 616 Worchester Street Herndon, VA 20170
Phone: PI: Topic#:	(703) 471-1518 Dr. Robert A. Sielski NAVY 01-057 Selected for Award
Title:	Effectiveness of Doubler Plates as a Permanent Repair Under Cyclic Loads in a Highly Corrosive Environment
Abstract:	The feasibility of the use of doubler plates as a permanent repair under cyclic loads in a highly corrosive environment will be demonstrated during the proposed Phase I effort. The work plan will include a review of literature, review of use of doubler plates, investigation of corrosion issues, investigation of crack initiation and growth, and investigation of ultimate strength issues. The review of the past use of doubler plates will include consultation with shipyards that have installed doubler plates as temporary repairs and with shipyards that have had to remove them to perform permanent repairs. Means will be found to reduce corrosion when doublers are placed over a corroded plate to which seawater may still gain access. Design of doublers will be developed of maintain the original structural integrity, including ultimate strength and fatigue and fracture strength. Chapter 100, Hull Structures, of Naval Ships' Technical Manual will be reviewed and a plan developed for updating it to reflect the results of the proposed research as well as other developments in the maintenance, inspection, and repair of ship structure. A plan will be developed for a Phase II effort to experimentally verify the results of the Phase I effort.A significant reduction in the cost of structural repairs to U.S. Navy ships is anticipated if doubler plates are used as permanent repairs. Avoidance of drydocking for structural repairs can save several hundred thousand dollars per repair. If there were only one such instance per year, the U.S. Navy would save several million dollars over a 10 year period, quickly amortizing the investment in this research. Commercial structural design standards such as those contained in the classification societies would benefit as new performance data of doubler plates is incorporated. This would lead to better monitoring & inspection procedures for these repairs as well as provide a more cost-effective strategy for decisions to permanently repair doubler plates.

BMA ENGINEERING, INC. 11429 Palatine Drive Potomac, MD 20854
Phone: PI: Topic#:	(301) 299-9375 Dr. Bilal M. Ayyub NAVY 01-057 Selected for Award
Title:	Effectiveness of Doubler Plates as a Permanent Repair Under Cyclic Loads in a Highly Corrosive Environment
Abstract:	The objectives of Phase I are to survey the use of doubler plates, and provide a methodology for developing quantitative technical rationale (criteria) for their design and their use limitations as a repair fix for surface ships. The specific tasks needed to achieve these objectives of the proposed effort can be enumerated as follows: 1. Identify commonly used repair fixes for surfaces ships, and summarizes experiences of shipyards, owners and operators, 2. Develop methods for stress analysis and residual stresses assessment, 3. Develop methods to assess corrosion concerns, 4. Develop methods for fatigue and fracture assessment, 5. Define the needs of design methods, 6. Develop methods to assess fabrication and maintenance issues, 7. Develop method for setting design criteria and limitations, 8. Demonstrate the methods and processes, 9. Develop a plan for Phase II of the SBIR effort in the form of prototype products with a high potential for successful commercialization, and 10. Optional Effort: Develop a database structure of use experiences, and software architecture and plan. The marine industry needs assistance in understanding the limitations of using doubler plates based on experiences by owners and shipyards. Also, there is a need to efficiently perform designs of doubler plates by recognizing any limitations of their use. The anticipated products from this SBIR effort are in the form of a database and software that would help in meeting the needs of the industry.

AEPTEC MICROSYSTEMS, INC. 15800 Crabbs Branch Way, Suite 290 Rockville, MD 20855
Phone: PI: Topic#:	(301) 670-6770 Mr. Thurston Brooks NAVY 01-058 Selected for Award
Title:	Wireless Interface to Programmable Logic Controllers (PLC)
Abstract:	The installation of Programmable Logic Controllers has become an integral part of shipboard control system. The most popular method for PLCs to communicate with external devices is through RS-232 connections using the MODBUS protocol. Newer PLCs support DeviceNet, ControlNet, or Ethernet networks, as well as Data Highway Plus, RS-232C, RS-422A, or RS-423A networks. As the Programmable Logic Controller becomes more prevalent throughout the ship, the use of RS-232 communication techniques increases the cost of the installation. In an effort to reduce the installation costs of shipboard control system, wireless communication to and from the PLC is required. This project will develop low-cost, single-chip wireless units for inclusion into manufacturers equipment to allow direct MODBUS (as well as, other standard protocols) communication between PLCs, other PLCs, SCADA equipment, and HMI interfacesCost Reduction Opportunities Decreased numbers of PLC's � Decreased amount of cable � Decreased number of cable/LAN drops � Faster installation and setup times � Greatly reduced sensor installation cost � Quicker system debug and fault isolation Decreased installation of shipboard control and monitoring systems Potential Commercial Applications Potential Commercial and Military Market Opportunities � Monitoring and control of factory floor � Power plant monitoring � Monitoring proper curing of molded materials, cements, concrete, etc � Monitoring the temperature of sensitive explosives to warn of dangerous situations � Monitoring the integrity of sealed containers � Cutting tool feed mechanism control � Process control in refinery and petroleum industry � Turbine operation and state monitoring � Pulp and paper feedwater monitoring � Monitoring of machinery condition in dangerous, hard-to-reach or moving sites � Water/Wastewater control � Material handling and shuttling � Lighting control

LUNA INNOVATIONS, INC. 2851 Commerce Street Blacksburg, VA 24060
Phone: PI: Topic#:	(540) 961-4516 Mr. Robert Harman NAVY 01-058 Selected for Award
Title:	Wireless Interface Modules for Programmable Logic Controller (PLC) Communications
Abstract:	The installation of Programmable Logic Controllers (PLCs) is a major cost driver for shipboard controls and monitoring systems. The proposed effort will develop and demonstrate a wireless interface for PLC controllers within a shipboard environment per the Navy's instrumentation requirements. All situations where reliable, low cost wireless links are established in lieu of wires/cables will directly result in major savings to the Navy during both the installation and maintenance lifetime and will result in reduced weight of the instrumentation system. Luna Innovations and its development team will first determine the best suited wireless technology for shipboard application (audio, radio, infra-red, etc), and develop a suitable wireless communications concept for shipboard data transfer while providing a cost effective approach. The research will focus on commercial-off-the-shelf (COTS) technologies and standards such as 802.11 and Bluetooth, resulting in modules that will communicate PLC information directly to a remote centralized control room, requiring non-line-of-sight transmission capability. A prototype interface module will be designed, developed, and then demonstrated at the end of the Phase I program. Luna will leverage previous wireless sensor development efforts and commercial production capabilities to satisfy the Navy requirements and bring the technology to immediate application and near-term product sales. Luna Innovations anticipates large non-defense related markets in industrial control systems, with specific applications including shipboard, spacecraft, aircraft, and nuclear/conventional power plant instrumentation systems. The previous success in this area resulted in a spin-off company dedicated to the production of wireless instrumentation systems for industrial rotating machine health monitoring utilizing off-the-shelf RF technology, and has over $1 million/year in revenue. Products resulting from this research will undergo immediate transition for introduction to the market.

LUNA INNOVATIONS, INC. 2851 Commerce Street Blacksburg, VA 24060
Phone: PI: Topic#:	(540) 953-4278 Mr. Robert Harman NAVY 01-059 Selected for Award
Title:	Portable Wireless Vibration Monitoring System for Shipboard Applications
Abstract:	The rapid development of wireless technology is creating new opportunities and challenges for instrumentation users and suppliers. Wireless sensor systems can significantly decrease instrumentation set-up time and cost, while simultaneously improving sensor signal-to-noise ratios and instrumentation system flexibility. Further, the arduous task of manually collecting accelerometer samples for purposes of machinery health assessment has created a situation where a wireless data conditioning and collection approach would have many benefits; primarily a reduction in man-hours devoted to data collection and reduced instrumentation installation and maintenance costs. Unfortunately, no wireless accelerometer systems are currently available that meet the needs of the Navy's Assessment of Equipment Condition Program and similar harsh environment applications. Luna Innovations proposes to develop a miniature, robust, low power, wireless system for measuring vibration utilizing the emerging RF and MEMS technologies with the primary objective being a target cost and performance equivalent to standard cabled accelerometers. This system will encompass both the sensor and the mobile unit used to collect data from multiple sensors in high-temperature, high-acceleration shipboard environments. Luna and its commercial partners will leverage previous wireless sensor development efforts and commercial production capabilities to satisfy the immediate Navy requirements and bring the developed technology to near-term market. Luna Innovations anticipates large non-defense related markets in industrial preventive maintenance systems and diagnostic instrumentation coupled with wireless transmission capability. Specific applications include shipboard, spacecraft, aircraft, and nuclear/conventional power plant health monitoring, transportation vehicle design and testing, and industrial rotating machine monitoring. The previous success in this area resulted in a spin-off company, dedicated to the production of wireless instrumentation systems for industrial rotating machine health monitoring utilizing off-the-shelf RF technology, and has over $1 million/year in revenue. Products resulting from this research will undergo immediate transition for introduction to the market.

KAZAK COMPOSITES, INC. 32 Cummings Park Woburn, MA 01801
Phone: PI: Topic#:	(781) 932-5667 Dr. Jerome Fanucci NAVY 01-060 Selected for Award
Title:	Conventional and Revolutionary Material Solutions for Composites Hatches and Scuttles
Abstract:	KCI, working with Bath Iron Works, proposes to design, develop and ultimately (in Phase II) install composite hatches and scuttles on DDG51's for sea trials. Our Phase I program has two important parts. First, we will select three DDG51 hatches and/or scuttles and develop replacement designs based on conventional composite material and processing technology. We expect leading designs selected in a Phase I trade study will be E-glass fiber reinforced sandwich panels produced by VARTM processing. We will investigate numerous matrix options including vinyl ester and epoxy loaded with fire-retardant thermosets, phenolics and new materials such as phthalonitrile, to deveop a design that cost-effectively meets MIL-STD-2031 requirements plus goals for weight and impact resistance. We will consider skin-stiffened designs as a potentially superior configuration to damage-prone sandwich panels. A second and perhaps far more important component of our Phase I research will be an investigation of a conceptual tri-component material system termed KCISTM. In Phase I will fabricate KCISTM test specimens and subject them to mechanical, EMI and FST testing. If this new materials technology performs as expected, it could be nearly impervious to expected shipboard fires conditions and could revolutionize the application of composites to shipboard structures. Demonstration of technology for making light-weight, cost-effective, damage-resistant composite hatches and scuttles accepted for use on DDG51 will open a market for similar products on a vast array of commercial and military ships. The same composite technology demonstrated for hatches and scuttles could be applied to a wide range of other shipboard structural parts. A new technology concept, KCISTM, if proven to perform as postulated in this proposal, could revolutionize the entire high temperature and fire-resistant composites industry by providing a material that is nearly impervious to fire at a cost that is competitive with conventional composites meeting the same performance requirements.

MISSISSIPPI POLYMER TECHNOLOGIES, INC. 13233 Webre Road Bay Saint Louis, MS 39520
Phone: PI: Topic#:	(228) 533-0825 Dr. Robert M. Springfield NAVY 01-060 Selected for Award
Title:	Low-cost Molded Polyparaphenylene Scuttles and Hatches
Abstract:	We propose using our unique, self-reinforcing, rigid-rod, polyparaphenylene-based thermoplastic for fabricating low-cost, lightweight scuttles and hatches. This thermoplastic, named Parmaxr Self-Reinforced Polymer ("SRP"), is an extraordinary high-performance polymer that exhibits the strength of metals. Parmaxr SRPs, however, are not long fiber composites, and thus are readily fabricated using conventional low-cost, automated molding methods. The most elegant design solution for hatch and scuttle fabrication is single operation molding. This is not possible with current sandwich-core composite technology, which requires complicated lay-ups. For scuttles and hatches, use of Parmaxr SRPs will offer the following advantages 1) lightweight, possibly including a Parmaxr SRP foam core (sandwich structure); 2) charring, providing an insulating, protective layer in fire situations without toxic gasses; and 3) simplified compression manufacturing methods, enabling production of cost-effective scuttles and hatches. During Phase I we propose to 1) compound Parmaxr SRPs into suitable formulations (ensuring acceptable mechanical, weight, EMI shielding, maintenance, and fire tolerance properties); 2) fabricate and test specimens to qualify formulations for use (with an emphasis on fire situation properties); 3) enter into a collaboration with one or more existing manufacturers of scuttles and hatches for development work; and 4) design prototype scuttles and/or hatches for Phase II development.Lightweight thermoplastic hatches will be commercially viable products to support the commercial cruise industry and perhaps even specialized fire door markets. This technology will offer high quality, low maintenance, low weight and potentially high volume/ low-cost conformal shape doors for commercial and DOD applications.

TRITON SYSTEMS, INC. 200 TURNPIKE ROAD Chelmsford, MA 01824
Phone: PI: Topic#:	(978) 250-4200 Mr. James Burnett NAVY 01-060 Selected for Award
Title:	Lightweight Advanced Composite Hatches and Scuttles
Abstract:	Triton Systems, Inc. proposes to design and develop a lightweight hatch/scuttle using a combination of advanced hybrid metal/polymer matrix composites, fire resistant polymer, and electro-magnetic interference (EMI) shielding polymer for the DDG 51 surface combatant. This combination of materials and processes enables the fabrication of a hatch/scuttle that meets the major design criteria of damage tolerance, EMI shielding, fire resistance, dimensional stability, low weight, low maintenance, and low cost. The hybrid metal/polymer composite is a structure that allows a direct transition from metal matrix composite to polymer matrix composite with efficient load transfer. In addition, the structure allows the co-mingling of metal matrix composite with polymer matrix composite in a unified structure, enhancing damage tolerance and EMI shielding. This approach also allows the co-casting of all of the closure, hinge and sealing fixtures simultaneously, reducing cost. Triton's InstaShield� polymer will be used for all external gluing, such as gaskets and seals. InstaShield� is a new conductive resin system that is formulated to high performance EMI shielding specifications, both for advanced composite laminations and adhesive applications.The composite hatch/scuttle proposed for development on this program is expected to have a direct impact on the DDG 51 ship by lightening the hatches and scuttles and reducing maintenance costs. Additional near term Navy applications include the DD21 surface combatant for the 21st century and retrofit onto other naval vessels requiring lower maintenance costs and lighter hatches. Commercial applications include hatches, scuttles and doors for commercial cargo vessels, and commercial cruise liners. Additional applications include missile casing end fittings, space truss tube end fittings, bicycle frame fittings, automobile frames, bodies and joints, drive shaft end fittings, propeller hub assemblies and airframe components of all kinds.

BMA ENGINEERING, INC. 11429 Palatine Drive Potomac, MD 20854
Phone: PI: Topic#:	(301) 299-9375 Dr. Bilal M. Ayyub NAVY 01-061 Selected for Award
Title:	Development of Probabilistic Design Primary Loads (Vertical & Lateral Bending) for use in a Weight-Optimized Structural Design of CVNX
Abstract:	The objectives of Phase I are to develop realistic, extreme primary hull girder loads necessary to facilitate the application of reliability-based methods for investigating the possibility of weight savings for aircraft carrier. In this study, an empirical-analytical methodology will be developed based on sea trials, spectral analysis and extreme value analysis that uses empirical data, operation profiles and motion analysis. The specific tasks needed to achieve these objectives of the proposed effort can be enumerated as follows: 1. Definition of reliability-based design and its needs in terms of load definition; 2. Assessment of primary loads; 3. Probabilistic characteristics of primary loads; 4. Extreme value analysis to determine the probabilistic characteristics of primary loads; 5. Load combinations; 6. Development of design criteria and limitations for primary loads; 7. Methods to assess weight reduction and optimization; 8. Demonstrate the methods and processes; 9. Develop a plan for Phase II of the SBIR effort in the form of prototype products with a high potential for successful commercialization; and 10. Optional Effort: Software architecture and plan. The marine industry needs assistance in accurately, effectively and efficiently assessing loads for aircraft carriers for the purpose of performing reliability-based designs by properly accounting for relevant uncertainties. Such design methods offer the potential for weight savings. The anticipated products from this SBIR effort would help in meeting the needs of the industry.

MANSOUR ENGINEERING, INC. 14 maybeck Twin Dr. Berkeley, CA 94708
Phone: PI: Topic#:	(510) 643-4996 Alaa Mansour NAVY 01-061 Selected for Award
Title:	Development of Probabilistic Design Primary Loads (Vertical & Lateral Bending) for use in a Weight-Optimized Structural Design of CVNX
Abstract:	One of the principle objectives of the project is to reduce construction weight of the CVN(x) and similar naval vessels. With this in mind, it is important to consider all loads influencing members scantlings. Some of the member scantlings are governed by local rather than global loads. Because of this concern, both local and global environmental loads will be investigated in this project if awarded to Mansour Engineering, Inc. In Phase I of the project, an operational profile will be constructed for the CVN (x) in consultation with NAVSEA and NSWCCD personnel, consistent with her service life requirements. Based on the operational profile and wave statistics in areas of operation, a multi-dimensional matrix of sea state (H1/3, Ta), heading angle (0), ship speed (V) and loading condition (W) will be established. A probability of occurrence of each "cell", i.e., each combination of (H1/3, Ta, q, V, W) will be estimated. The time domain computer program LAMB will be used to obtain the response of the ship in each "cell". The response shall include ship motion, global loads such as vertical and lateral bending moments as well as local loads in the various regions of the hull. As much as possible, slamming loads will be included. Long term distribution of ship motion and global and local loads will be determined, and from these, life time extreme values will be estimated. These values may be used as design loads or for guidance in determining member scantlings. Mansour Engineering, Inc. has been awarded and successfully conducted similar work in SBIR project "Reliability of Ship Structures," SBIR N00024-94-C-4059. In Phase II of the project, the strength aspects will be developed, including appropriate limit state equations for global and local structure requirements. As much as possible, the effect of fabrication imperfections on member strength will be included in the limit state equations. Mansour Engineering, Inc. has been awarded and has successfully conducted an SBIR project on this subject, "Structural Fabrication Tolerances and Structural Details," SBIR contract no. N00024-96-C-4123. In Phase III of the project, a weight optimization of the midship section will be conducted based on the extreme loads developed in Phase I and the limit state equations developed in Phase II. The proposed principal investigator, Dr. Alaa E. Mansour has conducted a similar study titled "Reliability-Based Method for Optimal Structural Design of Stiffened Panels," Journal of Marine Structures, Vol. 10, No. 4, June 1997. In addition to the principal investigator, there will be co-workers specialized in Naval ship technology including Dr. Robert Sieleski and Dr. Woei-Min Lin who was responsible for the development of the LAMP software at the Science Applications International Corporation. Significant weight savings in construction of the CVN (x) and similar USN ships are expected if it is demonstrated that an optimized midship section can be achieved with no decrease in structural integrity relative to an existing carrier. This has been demonstrated in other engineering fields (offshore, civil and mechanical) where weight savings can be accomplished when reliability-based structural design methods and optimization techniques are used. The proposed principal investigator is currently conducting a reliability-based study for ABS to reduce structural weight in the design of bulk carriers in order to modify Safe Hull Rules.

LEWIS INNOVATIVE TECHNOLOGIES, INC. 11405 Alabama Hiway 33, P. O. 624 Moulton, AL 35650
Phone: PI: Topic#:	(256) 974-8931 Mr. James M. Lewis NAVY 01-062 Selected for Award
Title:	Relay Replacement
Abstract:	The objective of this proposal is to prove the feasibility of building high-power Solid State Relays (SSR) using power MOSFET technology, and specifically to produce a unit to replace the Navy N-130 relays. Power MOSFET technology affords the capability to switch high voltage power at high currents with little on-resistance.Solid State Relays built with MOSFETs offer a number of advantages over SSRs constructed from SCRs and TRIACs, such as: lower on resistance, better control signal isolation (coil to contact isolation in relays), higher efficiency, and higher power handling capability.This research will result in the capability to produce efficient Solid State Relays that operate at higher voltages and currents than are currently available. These SSRs will have application in commercial power switching, telecom, and test equipment, where the use of electromechanical relays is currently the standard.

MILLENNIUM 3, INC. POB 5670 Glendale, AZ 85312
Phone: PI: Topic#:	(800) 843-4123 Peter Brady NAVY 01-062 Selected for Award
Title:	Relay Replacement
Abstract:	The Phase I objective of this R&D project is to confirm the feasibility of developing a solid state relay (SSR) to replace the problematic electromechanical relays in the automatic bus transfer (ABT) control circuitry of the in-plant load centers onboard CVN 68 class ships. The feasible design will closely match N-130 performance characteristics and have substantially increased reliability, low maintenance, the ability to accommodate six current configurations and cost significantly less than the $1800 replacement electromechanical relay.Anticipated Benefits: The solid state relay design will exhibit greatly increased reliability, low operational and replacement cost. It should be noted that the replacement cost for electromechanical relays is not guaranteed to remain approximately $1800 nor would it be unreasonable to expect the electromechanical relay failure rate to increase as the population ages. A successful SSR design could eliminate the probable prospect of substantially increasing electromechanical relay maintenance costs. Potential Commercial Benefits: The reliable, compact, flexible and cost effective design anticipated would permit pursuit of applications using the same or similar devices which in and of themselves would not justify the engineering and manufacturing costs necessary to develop solid state replacements but could use directly or with minor adaptation the replacement relay developed under this program.

KNOWLEDGE BASED SYSTEMS, INC. 1408 University Drive East College Station, TX 77840
Phone: PI: Topic#:	(979) 260-5274 Dr. Jayakumar Muthusami NAVY 01-063 Selected for Award
Title:	Ship Hull Intelligent Protection (SHIP) using Data Mining Techniques
Abstract:	The ultimate goal of this effort is to develop state-of-the-art software that performs data fusion on ship hull sensors including reference cell voltage, hull polarization voltage, hull current, salinity, temperature, etc. This research will lead to the optimal control of the Impressed Current Cathodic Protection (ICCP), the prediction of failures like paint removal, remaining anode life, and bridge formation as a means for reliably estimating the remaining life-cycle and planning for dry docking and other condition based maintenance (CBM). Reliable prediction and mitigation of hull corrosion is one of the single most important aspects for the condition-based maintenance (CBM) of the seawater system. No commercial product for performing this task is currently available.Extending the interval between dry docking periods one cycle (18-24 months), would allow substantial savings of over $8.6 million dollars per year for a fleet of 56 ships. The technology developed in this research would reduce the life cycle cost and increase the availability of the fleet.

MESOSCOPIC DEVICES, LLC 3400 Industrial Lane, Suite 7B Broomfield, CO 80020
Phone: PI: Topic#:	(303) 466-6968 Mr. Jerry Martin NAVY 01-064 Selected for Award
Title:	Low-cost gaseous and liquid oxygen production system
Abstract:	Requirements for oxygen production aboard aircraft carriers are changing. As more aircraft are converted to OBOGS, the need for liquid oxygen is decreasing. However, LOX requirements are not expected to drop to zero for a decade or more. For the next decade, there is a clear need for a flexible, compact system to produce LOX in small quantities. Mesoscopic Devices proposes to develop a compact gaseous and liquid oxygen production system using both gas-phase and cryogenic separation to yield a high-purity oxygen stream in a compact, modular system that can be baselined into new ships or retrofitted to existing ships. Our baseline design uses an innovative large-capacity pulse tube liquefier and high performance compact heat exchangers to yield high efficiency and long life. With no moving parts at the cold end, the system is tolerant of shock and vibration loads. The system can be configured to produce liquid and gaseous oxygen in any combination and is scalable to meet future needs. In Phase I, we will identify the most promising separation approach, define the optimum system configuration, and design the baseline system. In Phase II, we will build and test a complete oxygen production system.

BENEDICT ENGINEERING CO., INC. 3660 Hartsfield Road Tallahassee, FL 32303
Phone: PI: Topic#:	(850) 576-1176 Dr. Charles E. Benedict, PE NAVY 01-066 Selected for Award
Title:	Fully Automated Cargo Handling System
Abstract:	Automated storage and retrieval systems have proven effective methods of increasing efficiency and lowering overhead costs in many land-based industries. Implementing such systems in Navy aircraft carriers is the objective of the next generation CVNX aircraft carrier. Automated or semi-automated storage and retrieval systems (AS/RS) improve the efficiency of and reduce manpower required for storing, retrieving and tracking inventory. An (AS/RS) decreases time needed to resupply the ship and retrieve supplies on demand, while increasing the stowage capacity of the ship, a direct result from more efficient use of manpower and space in the cargo hold. Before a system concept can be developed to fit (or retrofit) the aircraft carrier or any vessel, a thorough spatial analysis must be performed to assess feasibility. This analysis will allow insight into design content selection, clearly show features most critical for a successful systems operation, and provide information for simulating the entire system. Thus, development time and cost of the scaled model in Phase II will be reduced, allowing for more effective design efforts to be spent on creating an evolutionary, cost effective, rugged, user-friendly, and operationally reliable S-AS/RS, which satisfies shipboard constraints and restrictions. No strike down is required.Development of this automated or semi-automated storage/retrieval system AS/RS as described in this proposal will benefit many existing industries by providing a low cost, reliable system which will improve inventory tracking and maximize storage density. Currently, billions of dollars are spent annually on the installation, maintenance and management of inventory through the use of existing storage and material retrieval system. The simplicity of the proposal concept, coupled with its multidirectional capability by use of multiple transporters will enable many businesses to automate their material handling of inventory, whereas in the past this was cost prohibited. Thus, they will become more cost competitive and profitable. Industries that will benefit include but are not limited to: military logistics commands, distribution warehouses, assembly lines, baggage handling (both airline and cruise ship), and parcel/package services such as FedEx, UPS, and the U.S. Postal Service. This system will also translate into future applications in the medical industry for homebound and handicap patient mobility.

ORBITAL RESEARCH, INC. 673G, Alpha Drive Cleveland, OH 44143
Phone: PI: Topic#:	(440) 449-5785 Mr. Troy Prince NAVY 01-066 Selected for Award
Title:	Autonomous Mobile Cargo Handlers For Carrier Automation
Abstract:	Operational requirements of the next generation aircraft carrier (CVNX) demand a level of hardware and software automation which current technologies have yet to meet. Of critical importance is the dramatic reduction of crew size. Orbital Research proposes the development of an advanced, robust, and reconfigurable autonomous handling mechanism designed to relieve sailors from physically exhausting manual labor associated with load transport, particularly during underway replenishment (UNREP). In Phase I of this work, Orbital Research will develop a discrete event simulation of cargo handling operations on board an aircraft carrier. This simulation will be used to conduct a system integration study of an Autonomous Mobile Cargo Handling (MCH) device that optimizes the logistics of the transport of stores and munitions on aircraft carrier. Phase I will close with a hardware design and a simulation optimization for the MCH device. Results will be leveraged into Phase II where a detailed, realistic scale model will be designed and constructed that will be mounted on a ship motion simulator.The Orbital Research modular flexible Robotic Materials Handling System is a readily adaptable design giving it diverse commercial applications. Commercial applications include: handling heavy payloads in difficult environments such as heavy manufacturing facility automation, metal forming operations, large component assembly processes, high speed flexible manufacturing for large scale components, and underway ship automation.

ADA TECHNOLOGIES, INC. 8100 Shaffer Parkway, Suite #130 Littleton, CO 80127
Phone: PI: Topic#:	(303) 792-5615 Dr. Craig S. Turchi NAVY 01-069 Selected for Award
Title:	Shipboard Bio-mechanical Oil Water Separator
Abstract:	In a ship's bilge, water mixes with oils, cleaners, and other liquids and dissolved solids to form a complex wastewater solution harmful to the marine environment. Naval vessels carry onboard oil/water separators (OWS) to prevent discharging oily wastes overboard. OWS systems can remove oil from water; however, serious problems arise when other contaminants, like detergents, are present. These ingredients cause oily water to form an emulsion, which fouls the OWS and prevents proper operation. Thus, the navy is seeking improved methods of separating oils from bilge water and preventing discharges of oily wastes. Acceptable techniques must be compact, automated, and effective on a wide range of waste compositions. Electrocoagulation (EC) is a method of electrochemically inducing coagulation of dissolved ions, oils, or suspended solids to create a readily separable phase. EC effectiveness has been demonstrated on heavy metals, fats, oils & grease, coal fires, and bacteria. However, use of the EC process has been limited due to its inability to effectively compete with land-intensive, chemical coagulation processes. ADA proposes to develop and demonstrate a shipboard EC system that will take advantage of key EC attributes - compact size and broad applicability - to enable this technology to be used for marine applications. The EC process can remove oils and dissolved metal ions from diverse wastewaters and can function as either a primary treatment step or as a pretreatment to other processes. For shipboard operation, EC attributes like compact size, diverse applicability, and minimal reagent usage become key advantages. A successful project will demonstrate EC's ability to treat oily wastewater to the targeted 15 ppm oil concentration regardless of the presence of detergents, solvents, and other contaminants. ADA's existing manufacturing base will be applied to provide these units for marine use.

JEWETT ENGINEERING LTD. 982 Sand Iron Drive, P.O. Box 7757 Incline Village, NV 89452
Phone: PI: Topic#:	(775) 832-0690 Mr. William F. Jewett NAVY 01-070 Selected for Award
Title:	High Volume Underway Replenishment Circulating Ropeway
Abstract:	The objective of this proposal is to develop and demonstrate a high volume underway replenishment circulating ropeway system to transfer stores and ordnance to aircraft carriers from supply ships. Circulating ropeway concepts will be developed and evaluated for at-sea future underway replenishment needs. Adaptation of circulating ropeway technology to existing replenishment installations will be considered.The anticipated result of the project is the conceptual development of a circulating ropeway system that will be used for future transfer of stores and ordnance to aircraft carriers from supply ships. Adaptive technology has the potential to increase the range of commercial applications for circulating ropeways where large differential movements or changing positions of terminal points are required.

WEIDLINGER ASSOC., INC. 375 Hudson Street 12th Floor New York, NY 10014
Phone: PI: Topic#:	(212) 367-3078 Dr. Ivan Sandler NAVY 01-070 Selected for Award
Title:	High Volume Underway Replenishment Circulating Ropeway
Abstract:	Weidlinger Associates, with John J. McMullen Associates and Leitner Lifts USA, will develop a high volume underway replenishment system. Several innovative circulating ropeway approaches will be investigated Weidlinger is responsible for the overall management of the SBIR effort and provides expertise in structural design, analysis of dynamic systems, and cable design and inspection. The performance of the cables in a marine environment and the dynamic and fatigue issues will be addressed. McMullen provides expertise for issues associated with ship architecture, including design and evaluation of the onboard equipment and components associated with the UNREP system, personnel and operational issues associated with the operation of the system, and compatibility of the system with other requirements of the delivery and receiving vessels. Leitner provides expertise on rope transport systems pertinent to the design, assessment and construction of the system and test models. The candidate approaches include a Simple Mono-Cable Rig, a Modified Mono-Cable Rig, a Bi-Cable Send / Mono-Cable Receive Rig, a Single Bi-Cable Rig, and a Dual Bi-Cable. The team will use a formal trade study process to evaluate the alternatives using weighting criteria developed with input from the Navy. One or two rigs will be selected for further development. As the size and capability of commercial marine vessels increases, one would expect an increased civilian demand for enhanced replenishment capability. Also the potential development of new sending, supporting, transporting and/or receiving components could find application in commercial funicular applications. Finally, adaptive technology has the potential to increase the range of commercial applications for circulating ropeways (for example, transferring loads and people directly from ships to tops of mountains and cliffs). There are potential applications for replenishment systems for drill ships and drill barges as well as floating production, storage and offloading systems, mobile offshore drilling units and undersea pipeline systems and risers.

APOGEE ENGINEERING, INC. 6059 Mission Drive West Bloomfield, MI 48324
Phone: PI: Topic#:	(979) 265-2026 Mr. David Lee Tanner,P.E. NAVY 01-071 Selected for Award
Title:	Water-Wet Pelletized Nitrocellulose Dehydration
Abstract:	Apogee Engineering Inc. proposes to R&D a unique process for dehydrating a slurry of 10% pelletized nitrocellulose (PNC) in water, ending with a final product of 60% PNC in a n-heptane slurry with a maximum of 0.1% water. The existing process involves drying the PNC to dryness in ovens and handling trays of material manually, then mixing it with very low flash point n-heptane. One can draw their own conclusions regarding the safety of this process. The Apogee goal is to use the best available technology so that the resulting process is: Operable and performs as required, Safe, Continuous, Energy and environmentally efficient, Minimal capital and operating cost and Composed of robust unit operations and equipment. Five options for processes have been proposed for evaluation and several others considered and rejected. The best process may be a combination of unit operations selected from among the five options. Membrane technology will probably be used. Principle investigator, David Lee Tanner,P.E. chemical engineer with over 45 years experience in diverse technologies, will establish the correct design basis for the process. A robust and superior process will be developed that will meet the needs of the Navy, other DOD components and the private sector.Benefits to the Navy, as a result of this research and development, will be the creation of a safer, automated and less labor intensive process for the dehydration of their pelletized nitrocellulose for use in composit cast modified double base explosives. The technology developed will also be of benefit to other DOD components. Apogee employees have conceived a unique processing step utilizing pervaporation membranes that may have utility in the pigment and dye industry, the pharmaceutical industry and the explosive and propellant industry in the private sector. This technology is anticipated to be patentable based on a percursory patent search. Successful development of this technology and obtaining patent rights would lead to a partnership with an established equipment manufacturing company that would be in a position to market this technology to an established customer base with an established marketing structure.

AVEKA, INC. 2045 Wooddale Drive Woodbury, MN 55125
Phone: PI: Topic#:	(651) 714-4293 Dr. Gary Pozarnsky NAVY 01-071 Selected for Award
Title:	Dehydration of Water-Wet Nitrocellulose by Enhanced Leaching Operation
Abstract:	AVEKA proposes the use of one of its proprietary leaching processes to dehydrate water-wet pelletized nitrocellulose (PNC). This is a process which will be safe, economical and will allow continuous processing during the dehydration step in the pelletization process. It is also a process that can utilize standard industrial leaching/extraction equipment with some modifications. The successful completion of this phase I research will be the adaptation of the AVEKA process to process the water-wet nitrocellulose into heptane dispersion without exposure to high temperatures and without changing the product characteristics. Phase II of this research will scale-up this process to production for integration into the present Navy facility for this process.The potential commercial applications for this water extraction technique are industries which presently deal with temperature sensitive materials and have a need to dehydrate or dry them. This process will be adapted for usage in the pharmaceutical and biochemical industries to dehydrate drugs and biologically derived materials which undergo decomposition at high temperatures.

CEFP, INC. PO Box 66618 los Angeles, CA 90066
Phone: PI: Topic#:	(310) 429-9402 Dr. Geoff Mcknight NAVY 01-072 Selected for Award
Title:	Improved Magnetostrictive Composites
Abstract:	The DOD has identified a need for high power broadband hybrid transducer arrays for use in surface ship sonar systems. The hybrid transducer design incorporates both magnetostrictive and piezoelectric elements into a novel double-resonant system that provides a previously unattainable bandwidth and power combination. The device currently incorporates laminated Terfenol-D materials for the magnetostrictive drive element. However, the laminating approach limits the design scope of the transducer device due to both limitations in lamination thickness (bandwidth) and stiffness properties available. These limitations can be overcome by replacing the laminated Terfenol-D elements with a robust magnetostrictive particulate composite assemblage described in this proposal. Development of magnetostrictive material that has tunable stiffness properties and large piezomagnetic coefficients. Commercial applications include sonar and hybrid sonar devices.

ETREMA PRODUCTS, INC. 2500 N. Loop Drive Ames, IA 50010
Phone: PI: Topic#:	(515) 296-8030 Mr. Jonathan D. Snodgrass NAVY 01-072 Awarded: 15MAY01
Title:	Enhanced Crystalline Alignment of TERFENOL-D
Abstract:	The effort proposed will validate the methods needed to achieve an enhanced crystalline structure in TERFENOL-D drivers. These new materials are expected to show substantially increased magnetostrictive performance (20-40% increase in strain, 10-20% reduction in hysteresis) as compared to baseline, large diameter ECG materials. This performance is expected to be on a similar level to FSZM materials, but will be available in much larger diameters than the 8mm maximum of FSZM. In Phase I, a rudimentary method for achieving enhanced crystalline alignment will be proven. Some of the critical process parameters will be explored, and others will be defined. In Phase II, this foundation of information will be used to develop a full scale process for reliable, day-to-day production of these materials. Phase II will also include an evaluation of full-sized samples to directly compare them against drivers in an established configuration. TERFENOL-D is a new competitive technology suitable for several different commercial and military applications, such as fuel injectors, braking systems, semiconductor bonding clamps, mine avoidance/removal, hazardous waste remediation, acoustic sources, dental tools, sono chemistry, construction tools, active machine tool control, rubber recycling, and enhanced oil recovery. ETREMA Products, Inc. was established to commercialize TERFENOL-D and transfer the technology from a laboratory discovery to industry and is now recognized as the world leader in the growing manufacturing sector for this material. ETREMA's marketing history is evident in the corporation's growth statistics. ETREMA has successfully established an international market for TERFENOL-D material, devices, and R&D services to develop solutions for industrial problems. Proof of its success is best illustrated in the year-over-year sales increases running between 50-100% over the last 6 years. ETREMA stands ready to implement any advantageous developments from the proposed effort. Substantial increases in the magnetostrictive performance will only accelerate the insertion of TERFENOL-D into the already growing market.

IMAGE ACOUSTICS, INC. 97 Elm Street Cohasset, MA 02025
Phone: PI: Topic#:	(781) 383-2002 Dr. John L. Butler NAVY 01-072 Selected for Award
Title:	Improved Magnetostrictive Materials
Abstract:	Objectives of this program include the development of magneto-active materials that yield improved performance, such as greater strain and reduced hysteresis loss, when compared to the current parameters of the magnetostrictive material Terfenol-D. We propose to consider the use of a recently discovered class of highly active ferromagnetic shape memory alloys (FSMAs). One of these FSMAs, Ni2MnGa, shows strains as high as 6 % and the possibility of low hysteresis loss; and thus, offers potential as a high-output transduction material. To this end we plan to use current and new measurements on the FSMA material to characterize it for transducer applications by state-of-the-art modeling. R. C. O'Handley's group at MIT will perform the FSMA material measurements. Based on this, analytical transducer models would be developed and used to evaluate the material as a transducer driver in potential transduction devices and applications. Our models would include electrical equivalent circuits, the finite element program ATILA and the program FLEXT. Transducers such the Tonpilz, X-spring and flextensionals would be considered as well as selected actuators. Our results will lead to optimized designs that could be fabricated in a Phase II effort.The development of this technology will permit the design and fabrication of high power actuators and transducers for military as well as commercial applications in the aerospace, automotive and control industries.

CREATIVE APPLIED TECHNICAL SYSTEMS 8320 Alban Road, Suite 900 Springfield, VA 22150
Phone: PI: Topic#:	(703) 913-3200 Dr. Judith F. Kitchens NAVY 01-073 Selected for Award
Title:	Development of Low-Cost Manufacturing Process for 1, 2, 4-Butanetriol (BT)
Abstract:	A process to manufacture low cost, high purity 1,2,4-butanetriol for use as a starting material in the manufacture of the plasticizer, 1,2,4-butanetrinitrate, will be developed. The starting material for the synthesis of 1,2,4-butanetriol will be the commercially available d,l-malic acid. The d,l-malic acid will be biotransformed under mild conditions using an anaerobic microoganism to reduce the carboxylic acid groups to the corresponding alcohol groups.An inexpensive source of high purity 1,2,4-butanetriol would allow greater incorporation of the 1,2,4-butanetrinitrate plasticizer in nitrocellulose propellants. Substitution of 1,2,4-butanetrnitrate for nitroglycerin in these propellants should extend the life of the propellants and decrease the hazards associated with their manufacture. The optical isomers of 1,2,4-butanetriol are of commercial interest as chiral building blocks for the synthesis of pharmaceuticals and specialty chemicals. The commercial demand for low cost, high purity (both chemical and optical) 1,2,4-butanetriol isomers is expected to increase rapidly in the next few years.

MAXDEM, INC. 140 East Arrow Highway San Dimas, CA 91773
Phone: PI: Topic#:	(909) 394-0644 Dr. Virgil Lee NAVY 01-073 Selected for Award
Title:	Development of an Efficient Low-Cost Manufacturing Process for 1, 2, 4-Butanetriol (BT)
Abstract:	There is a need to replace explosives, such as nitroglycerine, with more thermally stable materials for military and commercial applications. BTTN (1,2,4-butanetrinitrate) meets this need by offering a ten-fold increase in stability. Unfortunately, BTTN is prepared from an expensive material (1,2,4-butanetriol; BT), which currently costs $30-40/lb (compared to $0.50/lb for the glycerine, the precursor for nitroglycerine). For this reason, the Navy is interested in more cost-effective methods of preparing BT. This Phase I effort proposes a two-step, one-pot procedure for preparing BT that is based on well-precedented literature procedures. It is anticipated that this procedure will reduce material costs of preparing a pound of BT to less than $5. The proposed synthesis will be demonstrated in Phase I and scaled up to 30- to 100-gal reactors during the Option Period. The development of a more economically and commercially viable process for the preparation of 1,2,4-butanetriol (BT) would make 1,2,4-butanetrinitrate (BTTN) more affordable for military and commercial use as a stable replacement for nitroglycerine.

PHYSICAL SCIENCES, INC. 20 New England Business Center Andover, MA 01810
Phone: PI: Topic#:	(978) 689-0003 Dr. Hartmut H. Legner NAVY 01-074 Selected for Award
Title:	Drag Reduction in Water
Abstract:	An innovative program is proposed to exploit the dramatic drag reduction potential of microbubble layers on high-speed undersea vehicles. Under the turbulent flow conditions experienced by torpedoes, microbubble drag reduction is capable of providing the maximum friction drag benefit. Previous research has revealed that 80% of the skin friction drag can be eliminated through the introduction of small bubbles into the boundary layer surrounding the vehicle, but the application of the technology has not been vigorously pursued. The focus of this effort is to obtain extreme drag reduction levels by controlling the bubble characteristics and emphasizing techniques for high-speed vehicles. Three methods will be investigated experimentally: porous surface gas flow, water electrolysis and chemical gas bubble generation. All are capable of achieving high drag reduction levels, but the compatibility of each technique with the vehicle power system and weight/volume constraints will be carefully evaluated using an engineering model accounting for energy costs and system efficiencies. In the Phase I effort, experiments will be undertaken to establish the maximum drag reduction levels that can be achieved using controlled microbubble layers. The technique(s) providing the optimum performance and power system compatibility will be evaluated in large-scale experiments conducted in Phase II.The microbubble drag reduction technology is applicable for all marine vehicles. Commercial applications include supertankers, cruise ships, freighters, ferries and private power boats. Navy applications are high-speed torpedoes, AUVs/UUVs, submarines and surface combatants.

BOSCH AEROSPACE, INC. 7501 South Memorial Parkway, Suite 207 Huntsville, AL 35802
Phone: PI: Topic#:	(256) 882-9394 Mr. James H. Boschma NAVY 01-076 Selected for Award
Title:	Cycloidal Fan for Low-Noise Air Management
Abstract:	BOSCH Aerospace, Inc., a service connected disabled veteran-owned small business, is pleased to submit this proposal to develop and demonstrate an efficient, low-noise, low-maintenance air management system for shipboard ventilation. The concept is adapted from the Vertical Takeoff and Landing aircraft Cycloidal Propeller (CycloProp) development currently underway in SBIR Phase II Contract N68335-00-C-0201. CycloProp geometry places wing sections into rotation in a paddlewheel manner. In this geometry, air velocity is equal at all points across each wing's span. During rotation, the wing's angle-of-attack is changed in the sector of rotation requiring air acceleration. The result is very high-thrust and low noise at rotational speeds of about 20% of conventional propellers. CycloProp has demonstrated thrust of over 12 lbs/HP versus about three pounds for conventional propellers. This low-speed, high-thrust capability means less wear on bearings, lower energy consumption, low noise and lower maintenance. The research phases are: Engineering/Design, Fabrication/Integration, Testing/Demonstration. The project documentation will include design drawings, test reports, video, photographs and monthly Cost Performance Reports. Success will be exploited in the commercial sector whereSuccess will be exploited in the commercial sector where low-noise, efficient air movement systems are in demand. Benefits include low noise, low power consumption, high efficiency, and low wear on components, thus low maintenance. Commercial applications include worldwide forced air heat and cooling, electronic cooling applications in space, and other high-volume, low-pressure air or gas movement applications.

KRONOS AIR TECHNOLOIGIES 8551 154th AVE NE Redmond, WA 98052
Phone: PI: Topic#:	(425) 885-9739 Dr. Igor Krichtafovitch NAVY 01-076 Selected for Award
Title:	Flexible, Low-Noise Air Management
Abstract:	Current shipboard air movement equipment used to cool equipment and provide ventilation for personel are a source of noise in the operating environment and energy inefficient. This proposal describes a new air movement system utilizing Kronos Technology as an alternative air movement equipment on ships. At completion of Phase I a prototype shall be delivered for evaluation. A demonstration to cool electronic equipment is proposed to demonstrate this capability. Finally, a study to implement Kronos Technology in ventilation and equipment cooling shall be accomplished.Air movement devices utilizing Kronos Technology will be low-noise, low maintenance, flexible and adaptable. Combining air movement and purification allows for lower acquisistion costs, and reduced life cycle operating costs. Potential commercial applications include air purification and filtration systems, air filtration for unique spaces, specialized military colling applications, and embedded cooling for equipment.

TENSION SYSTEMS L.L.C. 114 Stoneway Trail Madison, AL 35758
Phone: PI: Topic#:	(256) 658-8222 Mr. Philip R. Cox NAVY 01-076 Selected for Award
Title:	Flexible, Low-Noise Air Management
Abstract:	Stepped Leader Air Movement (SLAM) uses staged, controlled ionization of ambient air to create airflow through non-conductive ductwork. It is a completely silent, highly reliable means of pumping air using electrostatics. It is also energy efficient -- requiring high voltage, but extremely low current. Multiple stages of electrodes increase air volumetric flow rate in direct proportion.Low-noise and low-vibration movement of cooling or heating air. Ultra-reliability is inherent in the design. Possible uses: submarines, surface vessels, SOSUS equipment cooling, medical ventilators, etc.

CONTINENTAL CONTROLS & DESIGN, INC. 1921 N. Gaffey Suite J San Pedro, CA 90731
Phone: PI: Topic#:	(310) 831-8669 Mr. James P. Hynes Jr. NAVY 01-077 Selected for Award
Title:	Projectile Inertial Navigator from COTS Instruments
Abstract:	This topic seeks a gun-hardened inertial navigator, suitable for guided munitions, made from low cost, commercially available instruments. After many years of waiting, and many failed starts, a Commercial Off The Shelf (COTS) 'Chip Gyro' is finally emerging. Analog Devices is sampling to us integrated (all silicon) iMEMS angular rate sensor prototypes designed primarily for the high volume automotive market. We will show in Phase 1 through analysis, simulation and extensive shock testing that these gyros can be combined with existing automotive grade silicon accelerometers and a single chip microcontroller to form a small, low cost IMU that will eventually occupy only 1 cu inch of volume. Performance will NOT be on par with current tactical grade optical and spinning wheel inertial instruments, but we will demonstrate their adequacy, with proper calibration, for dead reckoning ERGM and other guided munitions through the final stages of an engagement when the enemy is likely to locally jam the GPS timing signals. Everyone is excited about the eventual possibilities of MEMS. This project emphasizes the near term development of a low cost, low risk Inertial Measurement Unit based on COTS MEMS.

FIBERSENSE TECHNOLOGY CORP. 755 Dedham St Canton, MA 02021
Phone: PI: Topic#:	(781) 830-9690 Mr. Robert Hansen NAVY 01-077 Selected for Award
Title:	Projectile Inertial Navigator from COTS Instruments
Abstract:	Precision navigation based upon GPS and Inertial navigation is enabling precision weapons that are providing a revolutionary improvement in probability-of-kill Pk. Small, low cost MEMS based inertial systems permit the application of precision guidance to new low cost guided munitions.The technology is directly transferable to shoulder launched missiles, guided mortors, UAVs. In addition the technology is appropriate as an aig to GPS for vehicle navigation. There are numerous commercial applications for low cost GPS/Inertial

MAYFLOWER COMMUNICATIONS CO., INC. 900 Middlesex Turnpike, Building 8 Billerica, MA 01821
Phone: PI: Topic#:	(978) 436-9600 Dr. Kenneth A. Falcone NAVY 01-077 Selected for Award
Title:	Projectile Inertial Navigator from COTS Instruments
Abstract:	This Phase I study proposes to address the high cost of navigation systems suitable for guidance of gun-launched projectiles. The basic approach to reducing cost is to adapt for this purpose components which are under high rate production for the commercial market. Especially in the case of integrated electronic circuits and microfabricated mechanical devices, high production rate equates to low cost. We propose a navigation system which integrates the functions of an inertial navigation system, a GPS receiver and anti-jam antenna control. The INS is based on hardened versions of MEMS accelerometers and gyros which were designed for the large market in the automotive industry. The modest performance capability of these instruments is accommodated by strong aiding with GPS data. GPS receivers have been manufactured in large quantity for some time, and gun-hard versions have already been demonstrated. The addition of anti-jam signal processing gives the GPS receiver an additional margin of protection against both intentional and unintentional interference. This function is implemented in digital signal processing electronics, and when reduced to ASIC form can be produced at low cost.There is a clear need to improve the accuracy of long range projectiles through active guidance. There is at present no navigaiton capability suitable for this purpose which can be acquired at acceptable cost. This study proposes to integrate a set of components whose costs have been reduced due to COTS applications which will provide the required capability

MILTEC CORP. 6767 Old Madison Pike, N.W., Suite 200 Huntsville, AL 35806
Phone: PI: Topic#:	(256) 971-1970 Mr. Randy Wells NAVY 01-077 Selected for Award
Title:	Projectile Inertial Navigator from COTS Instruments
Abstract:	With the development of intelligent gun-launched munitions such as the US Navy Extended Range Guided Munition, there is a strong need for small, inexpensive, rugged and accurate inertial navigation systems (INS). Advances in MEMS sensors, miniature GPS receivers and A/J capability make a GPS-aided MEMS-based INS a strong candidate for this technology The objective of Phase I is to demonstrate the feasibility of a complete COTS INS solution that meets these requirements. Performance prediction of several externally aided INS design approaches will be performed. Packaging, electrical, and producibility issues will be addressed along with high-G testing. Phase II will involve prototype development and high-G testing of the proposed integrated INS.The potential commercial market for such an INS is orders of magnitude larger than any contemplated military market. Current automobile navigation systems rely completely on GPS. The INS would provide the navigation during times of GPS dropout caused by satellite LOS obstruction and signal interference. Other markets include commercial and private aircraft navigation and control, robotics, toys, medical equipment, surveying equipment, Geographic Information Systems, self-documenting digital photography systems used in highway maintenance, crime scene documentation, and insurance investigation.

FOSTER-MILLER, INC. 350 Second Ave. Waltham, MA 02451
Phone: PI: Topic#:	(781) 684-4114 Dr. Robert F. Kovar NAVY 01-078 Selected for Award
Title:	PBO Fiber-Reinforced Hydrocarbon Resin Composite for Low-Density, Wide Frequency Range Sonar Domes
Abstract:	Shipboard sonar domes based upon steel fiber-reinforced rubber currently show unsatisfactory performance as a result of narrow operating frequency range, high acoustic insertion losses and corrosion of metal fibers. Foster-Miller proposes to combine and extend our successful hydrocarbon resin, PBO fiber,VARTM and acoustic window technologies to develop a new class of sonar dome that is low density (1.23g/cc), hydrophobic, structurally sound and acoustically transparent over a wider frequency range than current sonar domes. Our low viscosity hydrocarbon resin will be VARTM-processed using low density (1.5g/cc), high performance PBO fiber preforms into a damage-tolerant, PBO fiber-reinforced, hydrocarbon resin sonar dome, called the Low Density Sonar Dome (LDSD), in one automated step. The LDSD will exceed the performance of current sonar windows, be lighter in weight and more economical. In Phase I, we will produce the LDSD and conduct acoustic testing to demonstrate feasibility. In Phase II, we will refine the material and process, scale-up to larger, more complex composite test specimens and conduct extensive acoustic and mechanical testing to qualify the LDSD for use in Navy shipboard applications. Our team includes experts in PBO fiber composites, hydrocarbon resins, VARTM processing and acoustic testing and Raytheon. (P-01401) The Foster-Miller LDSD will provide the U.S. Navy and commercial shipping industry with a sonar dome that is lower in cost, more durable and broader in acoustic frequency range than current shipboard sonar domes. Commercial applications include shipboard sonar domes and windows as well as other acoustically transparent, water-resistant composite structures such as remote submersible vehicles.

FULCRUM CORP. 9990 Lee Highway,, Suite 300 Fairfax, VA 22030
Phone: PI: Topic#:	(703) 385-5841 Mr. Vijay Kohli NAVY 01-078 Selected for Award
Title:	Improved Sonar Dome Window Materials that are Acoustically Transparent across a Wide Frequency Range
Abstract:	Current sonar domes do not provide best performance acoustically such as the insertion loss is high at high frequencies. Also, they do not cover wide band of frequencies of interest. Sonar domes materials have changed very little for over 20 years. There are new materials in the market which should be evaluated for the Navy applications.Development of the new material can be used for fishing boats, and radar domes for the aircraft industries.

MATERIALS SCIENCES CORP. 500 Office Center Drive, Suite 250 Fort Washington, PA 19034
Phone: PI: Topic#:	(215) 542-8400 Dr. Anthony A. Caiazzo NAVY 01-078 Selected for Award
Title:	Innovative Fiber Reinforced Composite Materials for Acoustic Window Applications (MSC P1B16-102)
Abstract:	Material systems that meet the insertion loss (IL) requirements of current acoustic windows have been shown to have difficulty meeting the structural properties required for undersea operation. In this proposal, Materials Sciences Corporation (MSC) outlines a research program to develop and demonstrate new and innovative fiber reinforced composite material concepts that have low IL across a wide frequency range yet have stiffness and strength characteristics necessary to survive undersea operational loads. The material solutions to be investigated will not rely on a tuned core to provide the required insertion loss characteristics; rather MSC plans to investigate innovative continuous fiber reinforced composite designs that are compatible with a low-cost composite manufacturing process. The leading candidate is a hybrid construction, comprised of a small amount of specialty glass and organic fiber reinforcement, that results in a composite material with a characteristic impedance that is acoustically transparent across a wide frequency range. Laboratory tests will be conducted to provide acoustic and structural response data needed to validate analysis tools used to select promising material candidates. Once validated, these analysis tools will be used to evaluate alternate acoustic window designs for sonar array systems proposed for the DD21.The leading application for the materials developed under this effort will be higher performing acoustic windows for use in U.S. Navy combatants such as the DD21 and submarines produced by Bath Iron Works, Litton/Ingalls Shipbuilding, and Electric Boat Corp. In addition to these direct applications, MSC will pursue application of the products of this SBIR to commercial sectors, which transmit acoustic signals through materials, including those in the fishing industry, the oil exploration industry and the medical industry.

CYBERNET SYSTEMS CORP. 727 Airport Boulevard Ann Arbor, MI 48108
Phone: PI: Topic#:	(734) 668-2567 Dr. Charles J. Jacobus NAVY 01-079 Selected for Award
Title:	Automatic Code and Data Migration in a Networked Computer Environment
Abstract:	In the DoD, many systems operate in multiple computer networks. Therefore, if a particular computer goes down, disabling the functions it performs, critical systems would be unavailable. If these functions could be moved to another hardware platform, no disruption of critical services would ensue. Cybernet has a patent for combining an Internet router with an applications-specific execution engine that caches algorithms. In this proposed effort we will extend the concept to routers that cache arbitrary code (not just code for message parsing and culling) for execution. The idea is to put a JAVA-like execution engine into all routers. Cybernet will:1) Develop a means that allows URLs to be resolved to where a dataset or function is cached, and not to a strict physical location,2) Develop an algorithm for moving datasets and functions from machine to machine,3) Develop a set of intelligent network and traffic monitoring/diagnosis processes, 4) Define a common runtime cache/shuffle system which is easily ported to each operating system platform, and 5) Determine the best way of bringing code user interfaces to a user who might be located anywhere on the network.A demonstration of this system will be implemented during the Phase I effort.The anticipated result of the proposed Phase I effort is to identify and prototype new and technically innovative web applications caching technology, which we plan to commercialize via Cybernet's NetMAX product line.

THE OPEN GROUP 29B Montvale Avenue Woburn, MA 01810
Phone: PI: Topic#:	(781) 376-8206 Mr. Douglas Wells NAVY 01-079 Selected for Award
Title:	Run-Time Reallocation of Heterogeneous Computing Resources
Abstract:	This proposal combines recent developments in the Java and CORBA communities with the real-time capabilities for the CORDS/GIPC group communications system. By enhancing those basic technologies with comonents that provide easily accessible fault-tolerance methods, the resulting system will be useful in military combat systems as well as commercial environments, such as factory floor automation and stock exchanges.This project will produce a system in which only one form of executable object exists, and that object can execute on any node regardless of the underlying platform. The system enables the development of efficient implementations of real-time, fault-tolerant applications. The project leverages the existing base of Java and Ada applications and programmers and fosters the creation of code without hidden security risks.

TIMESYS CORP. 4516 Henry Street, Suite 401 Pittsburgh, PA 15213
Phone: PI: Topic#:	(607) 625-4529 Dr. Doug Locke NAVY 01-079 Selected for Award
Title:	RTRACE - Real-Time Reconfiguration and Control Environment
Abstract:	TimeSys will develop the Real-Time Reconfiguration and Control Environment (RTRACE) solution to the reconfigurable distributed software problem by combining several independently developed activities originating with TimeSys technical professionals, both independently and in concert with efforts by the broader real-time systems standards community. We will develop and describe an approach for building an operating environment platform to allow real-time applications to run on multiple processor types. We will develop all of the infrastructure components required to implement typical Navy applications. This will include a RTSJ-compliant Java Virtual Machine (JVM) running on the TimeSys Linux/RT operating system. We will develop and describe an approach for building a distributed operating environment that supports the reallocation of system functions and/or applications across heterogeneous computing resources. We will extend the environment described above to incorporate the solution developed by our involvement in the Distributed Real-Time Specification (DRTSJ) for Java. In addition, we will evaluate CORBA-compliant components that can be used in conjunction with the DRTSJ, especially several components that are compliant with the Object Management Group's Fault Tolerance specification as well as with its real-time CORBA specifications.The proposed work through Phase II and beyond, will help to develop a technical solution that will begin to realize the vision of a truly "plug and play" total ship operating environment.

AEPTEC MICROSYSTEMS, INC. 15800 Crabbs Branch Way, Suite 290 Rockville, MD 20855
Phone: PI: Topic#:	(301) 670-6770 Mr. Thurston Brooks NAVY 01-080 Selected for Award
Title:	Fault Location in an Intelligent Open Sensor Network
Abstract:	Condition monitoring depends on information that is extracted from data gathered through a well-defined, yet dispersed, sensor network. The combination of embedded, self validating sensors, the development of a widely dispersed self-organizing sensor architecture and the intelligent agent software to facilitate the development and design of an emergent, self aware monitoring system will make available an up-to-date and accurate status, prognostic health assessment, diagnostic, and maintenance procedures. Because of the large number of on-board sensors and the fact that they will be widely dispersed, development of communications and controls technologies capable of coordinating these resources is needed. The intent of this research is to develop the necessary and sufficient connectivity to allow stable operation of a shipboard prognostic and health monitoring system and to formulate it as a dissipative system, able to recover from anomalies and disturbances without compromising mission compliance. We propose to develop a system where dynamics and stability are predicated on changing optimality and that cooperating agents form the basis for such rational behavior. Furthermore, for a system of operating agents to be successful, a communication architecture must be developed that allows for the free flow of data and information unencumbered by any spatial constraints.A successful approach will result in a blueprint for development of a robust, virtually indestructible network that will serve as a high-reliability communications link and sensor network for emergency and crisis management. It is expected to have wide application in areas such as Navy ships, hospitals, emergency response centers, nuclear plants, and any high value industrial asset or process.

MPI SOFTWARE TECHNOLOGY, INC. 101 S. Lafayette #33 Starkville, MS 39759
Phone: PI: Topic#:	(662) 320-4300 Dr. Murali Beddhu NAVY 01-080 Selected for Award
Title:	A Physics-Based Software Framework for Detection, Location, Isolation and Masking of Faults in Composite Sensor-Computer Networks
Abstract:	This Phase I SBIR Proposal responds to Topic 2001.1 Navy01-080, "Fault Location in an Intelligent Open Sensor Network." Proposer, MPI Software Technology, Inc, offers a physical-model-based approach to fault-location, operations-based management, and fault-tolerance of sensor networks. Such systems have relevance to DOD systems, including on-board systems for naval vessels, with corrolary application in other defense and dual-use settings anticipated, including automotive, homes, industrial and space-based applications. The state of the art incorporates stove-pipe subsystems involving sensors, computers, networks, and their separate management, with minimal management and fault-handling interactions. The purpose of this proposal is to create an integrated framework in which the sensors and computers work together in a more tightly coupled manner than is presently done in practice. Phase I studies integrated measurement and computation with the goal of providing enhanced accuracy of sensor measurement through fault-tolerant schemes. Phase II would create a prorotype based on COTS hardware and novel algorithms and software prototypes to be created by Proposer, based on Phase I studies and preliminary findings. Topic Navy01-080 requests fault-detection in sensor networks used in condition-based management of systems of interest. This proposal addresses that requirement, and goes further, offering fault-tolerance concepts, that will enable autonomous operation. Condition-based management can be applied to industrial, automotive, home, and other dual-use settings going beyond military applications. Scientific applications involving integration of measurements and computations are also a valid use, with potential for weather and other applied uses of such scientific computing with high societal value. This concept can be further enhanced to support model-predictive control scenarios of complex systems, which could include autonomous vehicles, or systems operating in harsh environments with no human intervention.

OCEANA SENSOR TECHNOLOGIES, INC. 1632 Corporate Landing Parkway Virginia Beach, VA 23454
Phone: PI: Topic#:	(757) 426-3678 Don E. Kennamer NAVY 01-080 Selected for Award
Title:	Fault Location in an Intelligent Open Sensor Network
Abstract:	The development of complex sensor networks for CBM has created the challenge of assuring the reliable transmission of sensor data across the network and the reliability of the actual data obtained by the sensors. Both classes of sensor and system error - false positives and failure to report a fault - can be costly and dangerous. The probability of these errors must be very low if CBM is to reach its potential. Oceana Sensor Technologies,Inc (OST) proposes to establish a model for self-testing of intelligent sensor networks, including wireless communication links, that can be adopted as an integral feature of emerging intelligent sensor systems. OST recognizes that, with the broad range of sensors and networks in existence and under development, an ad hoc strategy will become an endless series of tasks. Accordingly, OST's approach is general enough to work in any sensor-network configuration.The successful development and implementation of a self-testing CBM network of sensors has many implications. More reliable sensors and sensor networks for CBM give more accurate data over longer operating times. Smart sensors diagnose the exact location of a problem within the network so that humans need to spend less time diagnosing problems. The compliance of the open architecture network in accordance with IEEE1451 standards means it will interface with many vendors' sensors and network systems. And lastly, this technology will apply to any CBM system, DoD or commercial.

PROGENY SYSTEMS CORP. 8809 Sudley Road, Suite 101 Manassas, VA 20110
Phone: PI: Topic#:	(703) 368-6107 Mr. Michael P. MacMay NAVY 01-082 Selected for Award
Title:	Application of JINI Technology to Tactical System Integration
Abstract:	As submarine data processing systems become more complex and are comprised of more and more heterogeneous components, a new compatibility problem has arisen. Use of middleware packages, which broker data between applications using unique protocols and standards, has caused inter-subsystem connectivity problems, since each middleware solution, adhering to their own standards, is usually not interoperable with any other middleware. In addition to this problem, many middleware solutions are not backward compatible with previous versions of the same middleware. This situation, whatever the cause, has made a system, which should have a single data exchange standard, now support at least four different standards.At the base of this problem is that middleware products provide a useful service to the applications that use them. Middleware packages provide seamless data exchange services, platform independence, simplified system interfaces, and a standardized execution scheme. In fact, the middleware packages chosen or developed by each subsystem match the needs and requirements of those systems.A desired goal would be to create an architecture for systems to use to insure their interoperability, regardless of the middleware solution each has been developed under. This architecture would allow new subsystems to be integrated into the architecture with little effort.The results of this project are anticipated to have application to both commercial and military systems. Initially, this product would be best applied to government agencies and DoD where there is a real need to provide a better networking solution for system interoperability. In addition, since commercial industry has many of the same networking interconnectivity issues, there is a substantial market for the application of Jini technology in commerce, banking, and transaction-based services where multiple heterogeneous systems must exchange data in a common format.

TRIDENT SYSTEMS, INC. 10201 Lee Highway, Suite 300 Fairfax, VA 22030
Phone: PI: Topic#:	(703) 691-7781 Mr. Michael Stoddard NAVY 01-082 Selected for Award
Title:	Application of JINI Technology to Tactical System Integration
Abstract:	New standards are emerging for inter-process communication among technical systems under development. Subsystems using the CORBA protocol (IIOP) are sometimes tied to a specific vendor's ORB implementation without regard to portability in a heterogeneous network environment. As technology advances, upgrading is not cost effective. The JINI API, coupled with the Java Naming and Directory Interface (JNDI) API can provide a network architecture with a middleware layer that can relieve clients of many of the housekeeping tasks necessary to maintaining connections between clients and services. This is of particular interest when developing subsystems for the Virginia Class Submarine. One of the NPES subsystems of particular interest is the NTDPS. In this subsystem, laptops are assigned to particular tasks and may be moved to different places in the submarine. Docking ports are available in specific areas of the ship where it is anticipated that the laptops will be used. A wireless solution would be ideal in situations where no docking port is available. Using JINI in conjunction with a Bluetooth, the network can form itself when new hardware is nearby, thus greatly reducing the cost of maintenance and configuration Provides three primary benefits: development of a network infrastructure that provides the framework for extensions that provides inter-subsystem communication and a universal, spontaneous plug-and-play capability; a conceptual network architecture that provides wireless connection for clients and services regardless of location; and development of key services necessary in building a loosely coupled network environment including Accept/Deny procedures, Intrusion detection, Performance monitoring, and Fail over procedures.

PHYSICAL SCIENCES, INC. 20 New England Business Center Andover, MA 01810
Phone: PI: Topic#:	(978) 689-0003 Dr. Prakash B.Joshi NAVY 01-083 Selected for Award
Title:	Submarine Mast Detectability Reduction
Abstract:	Physical Sciences Inc., Sippican, Inc., and ARC Technologies propose to develop thin-film materials for significantly reducing the infrared and visible signatures of submarine masts. The proposed materials incorporate very thin film, conductive polymer electrochromic devices deposited on polymer substrates that can be bonded to existing radar absorbing materials like adhesive tape. The devices provide modulation of their infrared emissivity and visible reflectivity while being highly transmissive to microwaves (1-20 GHz). In Phase I, we will fabricate three different types of devices, measure their electrical and optical switching characteristics, and conduct experiments to estimate their microwave reflectance. We will subject the devices to some basic tests to verify their survival in operational environments. A preliminary system study incorporating the devices, visible/IR background sensors, and control electronics will be conducted. PSI will be responsible for device development and characterization. Sippican will be our commercial partner with experience in submarine mast manufacture; they will guide device development to meet systems integration and Navy requirements. ARC and PSI will perform microwave testing. In Phase II, the devices designs will be developed and optimized, subjected to rigorous environmental and performance testing, and integrated into a laboratory scale demonstration system.The proposed technology has wide applications in both military and commercial sectors. Military applications include US and allied submarines and army equipment. Commercial applications include telecommunications spacecraft thermal control and space electronics systems and electronic billboards and displays.

AMERICAN GNC CORP. 888 Easy Street Simi Valley, CA 93065
Phone: PI: Topic#:	(805) 582-0582 Dr. Ching-Fang Lin NAVY 01-084 Selected for Award
Title:	Low Cost Miniaturized INS for Torpedo Guidance and Control
Abstract:	Inertial navigation sensors and system technologies are essential for modern torpedo guidance and control. The objective of this Phase I project is to design a low cost miniaturized inertial navigation system (INS) for torpedo guidance and control using the AGNC-developed coremicroTM IMU. This miniaturized INS is an integration of AGNC's achievements in MEMS sensors and inertial navigation system development. The application of the MEMS inertial sensors makes it possible to build a small, light, low-power, and inexpensive INS. This miniaturized INS meets the torpedo requirements by its small size, light weight, low power, and reduced cost in design and production. It can be used in torpedoes and other vehicles for guidance, attitude determination and control. In Phase I, first, the hardware and software design of a miniaturized INS is proposed and investigated. The system design of the INS makes use of AGNC's rich experience in inertial navigation system (INS) development. Then, based on AGNC-developed technology, MEMS sensors for the miniaturized INS are designed, fabricated and integrated into the system hardware design. Next, an AGNC-developed MEMS testing and calibration system is used for design evaluation. Finally, an accuracy evaluation of the INS is performed by the way of a hardware-in-the-loop simulation.In addition to the application for torpedoes, because of its small size, low cost, and light weight, the miniaturized INS based on MEMS sensors has wide applications in navigation, control, and guidance. Examples of application areas include: miniature underwater vehicles, airborne, land vehicle navigators, micro UAVs, balloon-borne, and spaceborne vehicles, microrovers, micro tracking mechanisms, and space robots.

BARBER-NICHOLS, INC. 6325 West 55th Avenue Arvada, CO 80002
Phone: PI: Topic#:	(303) 421-8111 Mr. Dave Lowe NAVY 01-084 Selected for Award
Title:	Torpedo Affordability Improvements through Alternative Gearbox Lubrication and Sonar Transducer Uniformity
Abstract:	Oil lubricated gearboxes can be very costly with oil life and maintenance issues, complex sealing, seal shelf life issues, and oil sump requirements. Barber-Nichols Inc. will investigate alternative lubrication concepts to reduce these costs. Investigation areas will be water lubrication, dry or semi-dry lubrication, and material selection. These concepts have potential of significantly reducing gearbox complexity and resultant cost but include the challenges of boundary lubrication, heat rejection, and wear. BNI's experience with very highly loaded gearboxes, gear and bearing design with low viscosity fluids, and extreme applications (cryogenic to 2600F) make them uniquely qualified for success in this challenge. Today's torpedo sonar transducers are manufactured in large lots then individually tested and hand sorted into similar response groups. This hand labor and low yield manufacturing process adds significant cost to sonar arrays. Materials Systems Inc. has a patented injection molding process for piezocomposites that yields a large sheet of very uniform property piezocomposite material. When cut into pieces it provides very uniform elements. MSI has also developed manufacturing process controls and transducer construction methods that provide high electroacoustic repeatability among phased array elements and assemblies. MSI will use this technology to make torpedo transducers more affordable. An alternative lubrication gearbox could allow dramatic cost savings through decreased complexity, elimination of seals and associated shelf life issues, and an integrated feedpump design with resulting part count reduction. Reduction in gearbox size could enable added torpedo range or warhead size. These benefits would increase torpedo affordability. These concepts can also be used in other short life power transmission applications such as aircraft engine oil loss scenarios, missile applications, and space launch vehicle applications. Improving sonar transducer uniformity will also make torpedoes more affordable. If successful, the work performed in transducer uniformity under this program could practically eliminate the hand labor component of sonar assembly cost thereby driving torpedo system cost down. This technology could be used for all sonar applications in Navy and commercial ships, submarines, and other underwater applications.

INTELLIGENT AUTOMATION, INC. 7519 Standish Place, Suite 200 Rockville, MD 20855
Phone: PI: Topic#:	(301) 590-3155 Dr. Leonard Haynes NAVY 01-085 Selected for Award
Title:	Data Network for Submarine Command, Control, Communication, and Computers
Abstract:	This proposal details a low cost, low risk, innovative approach to implementing a network for connecting sensors to C4 systems within a submarine. Two devices will be built. The first device will eliminate the problem of powering sensors by using a single wire cable to provide power to the sensors. That same wire will also serve as the communication path for all the sensor signals attached to the single wire cable. The second device will be fully wireless. Both devices will be based on a new innovative approach to high bandwidth communication called ultra-wideband communication, where pulses pseudo-randomly modulated in time encode the information, rather than the conventional modulation of continuous waveforms. The wireless sensor link (WSL) and single wire sensor link (SWSL) are not two separate systems. In fact, our concept allows a SWSL unit to be converted to a WSL unit by simply pulling off the battery and antenna module and replacing it with a cable connection module. Likewise, the receiver unit is also the same, allowing signals to reach it via a receiving antenna or cable, but otherwise the electronics are the same. This is because the data is encoded in the same way for both cases.A key opportunity for TM-UWB radio is the industrial wireless LAN market. In 1997, wired LAN equipment sales for Internet service providers alone was $18B, while wireless LAN equipment sales were a mere $213M - a gap that is beginning to close even as the market scale increases. The system we propose offers significant flexibility in using both single wire and wireless nodes in the same network, with the same sensor package, and the same receiving hardware. For equipment health monitoring, our approach is compelling in that it provides a solution to the fundamental problem of how to power the sensors comprising a sensor network. We believe our system could easily become the routine method to interconnect sensors in future military and civilian health monitoring applications.

LUNA INNOVATIONS, INC. 2851 Commerce Street Blacksburg, VA 24060
Phone: PI: Topic#:	(540) 961-4516 Mr. Robert Harman NAVY 01-085 Selected for Award
Title:	Wireless Technology for Submarine Communication Systems
Abstract:	The rapid development of wireless technology is creating new opportunities and challenges for instrumentation users and suppliers. A significant portion of the cost for design, construction, and upgrade of Submarine Command, Control, Communications, and Computers (C4I) Systems relates to cabling and could be eliminated if wireless links replaced the cables. However, these benefits cannot be realized until the numerous technical challenges to implementing wireless links are overcome. Wireless transmission of data will also offer the potential to eliminate expensive cabling modifications, thus reducing installation and maintenance costs. The proposed Phase I program will first focus on determining which cables in the C4I system that can be replaced and the overall system impact. This includes compatibility and security issues, power requirements, system bandwidth capabilities and the problems associated with RF transmissions. Luna researchers will perform trade studies to assess the feasibility and payback of replacing candidate cables with wireless links. Requirements for those wireless links will be documented and used to evaluate commercial wireless technologies. Luna will draw conclusions about the feasibility of wireless links on submarines, and will offer creative ideas and a plan for adapting COTS products and/or developing new technologies and methods to meet the special requirements. The technologies and methods developed in this program can be applied to numerous military systems, potentially including Naval platforms, shielded data centers, underground command bunkers, and large space-borne equipment such as space stations. Luna also anticipates large non-defense related markets in industrial instrumentation systems coupled with wireless transmission capability. Luna's previous success in this area has resulted in a spin-off company dedicated to the production of wireless instrumentation systems for industrial rotating machine health monitoring utilizing COTS RF technology, and has over $1 million/year in revenue.

LIVERMORE SOFTWARE TECHNOLOGY CORP. 7374 Las Positas Road Livermore, CA 94550
Phone: PI: Topic#:	(925) 449-2500 Dr. Bradley N. Maker NAVY 01-086 Selected for Award
Title:	Computer Simulation Improvements For Utilization of COTS Equipment in Naval Combatants
Abstract:	By improving computer simulation capability for shock isolation systems, this proposal will support the U.S. Navy's efforts to incorporate the use of commercial-off-the-shelf (COTS) equipment items in combat environments. Attention will focus on shock environments, including hostile underwater explosion (UNDEX). Under this proposal, the LS-DYNA finite element software will be enhanced and optimized for application to COTS certification against UNDEX environments. The methods of modal representation, substructuring, and component mode synthesis will be developed in LS-DYNA to greatly enhance its efficiency in simulating the gross structural response of the ship. This will allow simulation detail to be concentrated on the shock isolation system. In the phase I activity, new software features for "flexible-rigid body" modal representation will be implemented, and an anticipated 10x improvement in overall simulation speed will be demonstrated. Interfaces will be added to support user-supplied, potentially proprietary, shock isolation system models. In the phase II activity, substructuring and component mode synthesis will be added to LS-DYNA, an automated simulation procedure will be developed to simplify application of these new methods, and large scale validations of the new software will be performed. The new capabilities developed under this proposal will become a permanent part of the standard production version of the LS-DYNA software.

WEIDLINGER ASSOC., INC. 375 Hudson St FL 12 New York, NY 10014
Phone: PI: Topic#:	(212) 367-3094 Dr. Raymond P. Daddazio NAVY 01-086 Selected for Award
Title:	Transient Shock Resistance of COTS Electronics
Abstract:	United States Navy military shipboard equipment designers have utilized of military rated components in their designs together with the application of military specifications to ensure survivability during conflict. These designs were subject to long development cycles and unique point designs with the associated high costs. Due to the rapid growth in commercial electronics, and especially in computing, commercial solutions to shipboard equipment designs have become appealing. Little growth in the defense budget coupled with mandated acquisition reform has led to new shipboard equipment designs with increasing application of Commercial-Off-The-Shelf (COTS) solutions. The positive potential to the Navy in utilizing COTS equipment is enormous. These include the ability to access state-of-the-art technology solutions in its surface ships and submarines coupled with avoiding costly point designs to military specifications. To realize the advantages of utilizing COTS equipment, the uncertainty in understanding the response of COTS equipment to shock loads must be addressed. This will help ensure that the COTS systems will continue to support the war fighter during conflict. Our Phase I research will identify and develop concepts to address and reduce these uncertainties. An improved analytical modeling capability resulting from this research and associated COTS equipment certification process may be used by the commercial shipbuilding industry. This research will allow the evaluation of new designs and associated risks related to vibration and noise control as well as dynamic loads encountered due to wave slamming, sea keeping, grounding, docking loads and collisions at sea.

LAKOTA TECHNICAL SOLUTIONS, INC. PO Box 2378 Ellicott City, MD 21041
Phone: PI: Topic#:	(301) 725-2727 Mr. J. Robert Pence NAVY 01-087 Selected for Award
Title:	Low Cost Compression Techniques Applied To Encrypted Data Distribution System
Abstract:	The Cooperative Engagement Capability (CEC) was developed to share unfiltered sensor measurements between cooperating units (CU) within the battlegroup. This sharing of information facilitates the development of a common air picture. However, due to bandwidth limitations, there is a limit to the number of units that may receive this information. Data compression techniques can be applied to increase the number of units which are able to exchange these sensor measurements. This Phase I proposal will examine the current state of data compression and develops/analyzes a lossless compression algorithm for inclusion within the CEC's Data Distribution System (DDS).The utilization of a lossless compression algorithm with the Cooperative Engagement Capability's Data Distribution System or any other tactical data link will enhance the information superiority achievable by US military forces.

PROGENY SYSTEMS CORP. 8809 Sudley Road, Suite 101 Manassas, VA 20110
Phone: PI: Topic#:	(703) 368-6107 Mr. Michael P. MacKay NAVY 01-087 Selected for Award
Title:	Low Cost Compression Techniques Applied To Encrypted Data Distribution System
Abstract:	What is required is to step "out of the box" and consider solutions that take the needs of a real-time system like the Cooperative Engagement Capability (CEC), as well as the data it is exchanging, into account to design compression solutions that work for the system as a whole. While there may be some development savings in going to the commercial world for these solutions, in the end it is the solution that takes the system into account that will provide the best answer. Progeny Systems has a long history with years of experience in real-time data delivery and processing. Some of the solutions we are providing to the Navy in the Advanced Undersea Warfare Concepts (AUSWC) program solve the same problems in data and bandwidth conservation.The results of this project are anticipated to have application to both commercial and military systems. Initially, this product would be best applied to government agencies and DoD where there is a real need to provide a better networking solution for system connectivity. As such, initial customers are intended to be PMS401, PMS415, PMS425, and PMS450 programs. Since the research is targeted toward interoperability and seamless exchange of information across limited bandwidth channels, the resulting technologies from this topic could be used support most areas of the Navy's system development efforts. In addition, since commercial industry has many of the same networking interconnectivity issues, there is a substantial market for the application of this technology in practical application. During the development cycle, we will be in constant contact with industry, military, and university experts in the related fields. This will also provide us with the opportunity to identify new methods for acquiring better methods and techniques using industry standard development environments.

VISTA RESEARCH, INC. 755 N Mary Ave Sunnyvale, CA 94085
Phone: PI: Topic#:	(408) 830-3321 Dr. Raul Martinez NAVY 01-087 Selected for Award
Title:	Novel Data Compression Technique for the CEC System
Abstract:	A novel data compression algorithm will be developed for the Cooperative Engagement Capability (CEC) system. Key features of the algorithm include high speed, low cost, and interoperability with encryption. The algorithm will be computationally fast to satisfy CEC's latency requirement. By reducing redundancy in the bit stream, data compression not only will enhance CEC's effective bandwidth but also will enhance security. The compression will be lossless in an information sense. Three classes of data compression methods will be investigated for suitability: entropy-, dictionary-, and prediction-based. Extensive testing and performance evaluation will be performed.Because bandwidth constraints limit the transmission capacity of military and commercial systems, a data compression method that is fast, encryption-capable, low cost, and suitable for use in a distributed system should be of interest to military agencies and commercial entities. Its encryption compatibility should make the algorithm particularly suitable for systems that broadcast proprietary or other sensitive data. The field of wireless communications is exploding and should provide a variety of opportunities for applications in the near future.

CHARLES RIVER ANALYTICS, INC. 725 Concord Avenue Cambridge, MA 02138
Phone: PI: Topic#:	(617) 491-3474 Mr. Harald Ruda NAVY 01-089 Selected for Award
Title:	Automatic Workload-Sensitive Task Allocator (AWOSTA)
Abstract:	The Navy is under pressure to reduce shipboard manning levels in the face of ever-intensifying tactical responsibilities, battlespace tempo, and weapons lethality. There is thus an increasing need for team coordination, cohesiveness, and especially adaptability in operator task allocation during intense tactical operations. We propose to address this by designing a generic distributed agent-based Automatic Workload-Sensitive Task Allocator (AWOSTA) that: 1) identifies, defines, and elicits the static personalities, behaviors, and knowledge of each team member; 2) identifies and assesses the dynamic behavior of the team and each individual member of the team; 3) displays individual and team workload to the team supervisor in an intuitive fashion; and 4) recommends re-tasking options to ensure optimal team performance throughout an engagement. We propose a multi-faceted approach to workload assessment (physiological-, subjective-, and performance-based), the use of belief network technology to combine disparate measures of loading and performance, and an innovative task reallocation logic to optimize team performance. The Phase I effort will develop a prototype to explore the general feasibility of the overall approach. In Phase II we will focus on the design and implementation of a prototype for a specific shipboard system such as the Area Air Defense Commander.The commercial potential for a system with the capability to monitor team workload and stress and the ability to distribute tasks among members of the team based on the measures is very high. Some of the most promising possibilities involve applying the technology in technical support centers, commercial air traffic control, police and other emergency dispatch operations.

CHI SYSTEMS, INC. Gwynedd Office Park, 716 N. Bethlehem Pike, Ste 30 Lower Gwynedd, PA 19002
Phone: PI: Topic#:	(215) 542-1400 Dr. Floyd Glenn NAVY 01-089 Selected for Award
Title:	Dynamically Optimized Team Performance
Abstract:	The System for Management and Allocation of Recurring Tasks (SMART) is proposed to facilitate allocation of team tasks in complex Navy systems. SMART offers a model-based framework for identifying the sequence of tasks which a Navy team performs along with specification of all relevant performance-influencing factors for the team members, tasks, and context. A variety of techniques for task scheduling and allocation will be developed and tested. A cognitive model is employed to specify task dynamics, task interactions, and analytic projections of workload. A user interface for a human task manager will provide a dynamic display of diverse kinds of information that are relevant in assessing the relative effectiveness of different team members in performing different kinds of tasks based on both perseverant and transitory characteristics of the team members, the tasks, and the operational context. Indices of team member cognitive state will include various relevant physiological indicators and some self-report measures for affective factors. Additional indicators of perseverant characteristics such as measures of experience, training, and general mental abilities will also be provided. A series of experiments will start with a completely `manual' scheme for task allocation with succeeding experiments evaluating increasingly complex concepts for aiding and automation of task allocation.SMART is expected to provide a valuable asset for many emerging Navy (and other military) tactical systems which are increasingly comprised of reconfigurable workstations and thus provide broad opportunities for task reallocation as a means to achieve the aggressive goals for reduced manning faced in all new system developments. Non-DoD applications are envisioned for air traffic control, telephone operator management, and other environments with replicated workstations and severe time and workload pressure.

MICRO ANALYSIS & DESIGN, INC. 4900 Pearl East Circle, Suite 201E Boulder, CO 80301
Phone: PI: Topic#:	(407) 482-6404 Mr. Jon French NAVY 01-089 Selected for Award
Title:	Dynamically Optimized Team Performance
Abstract:	A software-based system is proposed, the Dynamically Adaptive Resource Tool (DART), to help operators manage information intense monitoring systems in militarily relevant operational settings. Different approaches to managing team workload overload, under load and losses of vigilance are discussed. The approach with the most likelihood of success is described as a system that uses adaptive automation to enhance information gathering operator resources. It is conceived to be an interface used for both training and operations that 1.) displays the current effectiveness of an operator based on past or expected performance, 2.) provides visual and auditory means to alert the operator to significant decreases in effectiveness, 3.) adjusts information transfer rate and presentation rate based on the operator's effectiveness and 4.) to re-distribute task workload to other team members as needed.The objective of this approach is to integrate sophisticated workload modeling and analysis tools to help manage real-time operator performance. The DART will be able optimize the distribution of information, resources and enhance the performance of the system. Such a tool would be ideal for training since other operators on the team would not have to be present for the system to respond to pre-programmed scenarios.

NOVA ENGINEERING, INC. 5 Circle Freeway Drive Cincinnati, OH 45246
Phone: PI: Topic#:	(513) 642-3159 Mr. Steve Warden NAVY 01-090 Selected for Award
Title:	TBMD Tactical Telemetry Transmitting System
Abstract:	Upgraded telemeter requirements for TBMD (Theater Ballistic Missile Defense) post-launch monitoring will include a new tactical mode for defensive operations during armed conflicts. Multiple Standard Missiles from multiple platforms may be launched nearly simultaneously. System analyses have indicated that under this scenario and current IRIG PCM/FM channel allocation guidelines, unacceptable adjacent channel interference will degrade critical telemetry communications. Due to the explosion in commercial wireless communications, further spectral allocations for military telemetry are not foreseen, and current allocations are even being reduced. Thus, improvement in the spectral efficiency of tactical telemetry signals is warranted. Data compression, forward error correction, high-order modulations, and dynamic multiple access techniques can all be applied, as part of a thorough and detailed system analysis to make better use of the available spectrum. In addition to Nova Engineering's substantial experience in solving complex communications problems, the TBMD program would certainly benefit from our Hypermod transmitters and receivers. This innovative technology utilizes SOQPSK and multi-h CPM modulation to provide a two to three-fold increase in spectral efficiency over conventional PCM/FM signalling; prototypes exist today. Detection efficiency approximately equals that of PCM/FM and all modulation schemes have constant envelopes, allowing use of non-linear RF PA's. A set of operational and transmitter requirements developed in Phase I will transition to a high performance telemetry transmitter for NSWC applications, with additional direct application to other DoD flight test ranges and industrial users.

INTEGRATED SENSORS, INC. 502 Court St., Suite 210 Utica, NY 13502
Phone: PI: Topic#:	(315) 798-1377 Mr. Walter Szczepanski NAVY 01-091 Selected for Award
Title:	Interference Suppression Techniques Development for Future Combat Scenarios
Abstract:	Integrated Sensors Inc. and Syracuse Research Corporation propose to develop and demonstrate techniques that effect practical, operationally meaningful, simultaneous mainlobe/sidelobe jamming cancellation for existing radars while preserving target angular accuracies and permit operation in littoral (clutter) environments. The primary emphasis will be: (a) investigate practical interference suppression techniques for use in existing radars against current and projected interference sources, (b) develop architectural requirements, analyze and quantify detection and target angular accuracy, and (c) demonstrate performance estimates and architectural feasibility. Four associated architectures will be examined: (1) a modified sequential Sum-Difference-Auxiliary adaptation scheme for combined constrained multiple sidelobe canceler/mainlobe canceler operation with non-separable antenna patterns, (2) a Sum-Difference-Auxiliary architecture, but with the addition of pre-cancellation Doppler filtering to enhance clutter suppression, (3) a Sum-Difference-Auxiliary architecture and pre-cancellation Doppler filtering but with the addition of frequency subbanding to extend performance for wideband operation, and (4) an interference suppression option for very wideband stretch processing receivers. Our demonstration plan includes an experimental system including a phased array radar as part of a comprehensive Phase I and Phase II program, eventually leading to implementation of jamming suppression processors for retrofit into existing Navy radars.The technology developed can become an integral part of many future radar system designs for both military and commercial applications. A variety of applications for shipboard, airborne, spaceborne and ground based passive receive systems can significantly benefit as well. Commercial applications for communications systems will also benefit from this technology development.

TECHNOLOGY SERVICE CORP. 11400 West Olympic Blvd., Suite 300 Los Angeles, CA 90064
Phone: PI: Topic#:	(301) 565-2970 Dr. Menachem Levitas NAVY 01-091 Selected for Award
Title:	Interference Suppression Techniques Development for Future Combat Scenarios
Abstract:	The complex jamming threat to Navy radars, such as the AN/SPY-1 radar family, consists of barrage and modulated noise jammers on the one hand, and analog and digital deceptive jammers on the other. Vulnerability to jamming will generally increase with growing radar sensitivity and the evolving Digital Radio Frequency Memory (DRFM) based deceptive jammer technology and its broad proliferation. This proposal is concerned with waveform and processing techniques to enable existing radar systems to maintain their operational performance in the presence of deceptive jammers. (Unlike techniques required to counter noise jammers, the above do not require changes to array beamforming architecture and receiver design.) In the proposal, we first discuss fundamental repeater jammer limitations. We then describe several potential techniques to counter repeater jammers, whose respective enabling technologies are deemed to exist. They are separated into several processing categories, and include both passive and active approaches. Several techniques are selected for study during the basic Phase I period, and a simulation package is proposed to be defined in the Phase I Option and developed in Phase II, along with validation tests, in support of off-line analysis and inclusion in radar upgrades.This research and development effort could lead to clear understanding of fundamental repeater jammer limitations - particularly of the DRFM variety - and of techniques to counter such threats both in existing radar systems, through upgrades, and in future radars. A simulation package to be developed in Phase II of this SBIR will support the insertions of such techniques to various radar systems - future and existing. The products of this effort are expected to be applicable to all military radars within the context of shipboard, airborne and space-borne applications.

DIGITAL SYSTEM RESOURCES, INC. 12450 Fair Lakes Circle, Suite 500 Fairfax, VA 22033
Phone: PI: Topic#:	(619) 683-3477 Mr. Donald Coleman NAVY 01-092 Selected for Award
Title:	Dynamic Sensor/Weapon Alignment Algorithms
Abstract:	Development of concepts and associated algorithms for dynamic alignment of ship sensors and weapon systems is proposed. Correlation processing of ship sensor data provides the opportunity to develop composite tracks and calculate the difference or track offsets in the constituent sensor tracks that are each based on single sensor measurements. Both the short and long-term time averages of track offsets of correlated sensor tracks from different sensors are useful data for sensor/weapon alignment. The sensor misalignment, regardless of the cause, would be dynamically available on a track-by-track basis by extracting the track offsets measured in the track correlation process. The proposed alignment algorithm development would address misalignments caused by a multiplicity of conditions such as ship's flexure, temperature differentials and navigation sensor latency. The technique would also address sensor misalignment caused by the effects that refraction and ducting have on microwave propagation by sensors operating at different wavelengths. DSR proposes an alignment algorithm integrated into a COTS based multi-source data fusion architecture. This architecture supports an innovative data processing technique that leverages correlated platform-centric sensor tracks to form a platform-centric dynamic sensor alignment algorithm. The algorithms would be inserted into legacy and/or developmental multiple-source data fusion processing architectures.The sensor-to-sensor/weapon alignment algorithm is envisioned as a processing module suitable for other surveillance requirements including law enforcement, air traffic control, drug interdiction, ship multi-radar based navigation and collision avoidance and commercial vehicle location and tracking.

MILTEC CORP. 6767 Old Madison Pike, N.W., Suite 200 Huntsville, AL 35806
Phone: PI: Topic#:	(256) 971-1970 Mr. Randy Wells NAVY 01-092 Selected for Award
Title:	Dynamic Sensor/Weapon Alignment Algorithms
Abstract:	Electronic Support Measures and infrared sensors for the next generation US Navy surface ships will have considerably tighter angular accuracy than today's systems such as the Advanced Integrated Electronics Warfare System. The improvement in accuracy is motivated by factors such as: requirements to support track correlation to other combat systems sensors, de-interleaving closely space emitters, and cueing combat system fire control and multifunction radars such as the AEGIS AN/SPY-1D. The objective of the Phase I effort is to determine the feasibility of dynamic alignment methodology that can be utilized between the ship sensor systems and weapons systems. This will be done through ship structural bending analysis and covariance analysis for various inertial attitude reference systems including GPS phase measurements. Innovative candidate Automatic & Dynamic Alignment System (ADAS) approaches will be analyzed evaluated for cost, cueing sensor bias accuracy, time latency, and platform-independence. Phase II will involve ADAS prototype development, HWIL & SWIL testing, as well as at sea testing.The anticipated modularity and compatibility of ADAS should attract users in the commercial market who have a need for multi-device alignment such as commercial aircraft, ships, land vehicles, air traffic control, and oil explorations.

AEPTEC MICROSYSTEMS, INC. 15800 Crabbs Branch Way, Suite 290 Rockville, MD 20855
Phone: PI: Topic#:	(301) 670-6770 Mr. Thurston Brooks NAVY 01-093 Selected for Award
Title:	Advanced Personal Communicator (APC)
Abstract:	As the complexity of the battlespace has grown exponentially and the outcome of the engagement is increasingly a function of communications speed, accuracy and relevance, it is critical to have a always-connected ship-board personal communications system that has the ability to support information-in-place which receives and transmits location and context intelligent information, supports decision processes and disseminates orders for action in near real-time. Inter and intra team coordination requires ubiquitous and interoperable communications to support the tremendous demands being placed on disparate and dispersed groups whether at the individual, specialized or ad-hoc group, division, ship, or higher level. This proposal addresses the development of a smart, self-organizing, ad-hoc connectivity-aware wireless network that will enable the essential communications connectivity between and among these discrete requirements. Because all communication demands are not the same, a suite of interoperable wireless devices must be employed to provide location and context intelligent voice, data, and multimedia communications. This concept will be critical to achieving an Advanced Personal System. Additionally, it is imperative to implement a technology to provide a security level that provides a low probability threshold for detection and will support multilevel access protections that prioritizes bandwidth.A successful approach will result in a blueprint for development of a robust, and fault tolerant ubiquitous and ad-hoc wireless network that provides location and context intelligent voice, data and multi-media communications that will serve as a high-reliability wireless extension of existing networks. It is expected to have wide application in areas such as DOD operational forces, inter and intra ship communications, hospitals, emergency response centers, nuclear plants, mobile and remote workers, and any high value industrial asset or process.

AMERICAN GNC CORP. 888 Easy Street Simi Valley, CA 93065
Phone: PI: Topic#:	(805) 582-0582 Dr. Ching-Fang Lin NAVY 01-093 Selected for Award
Title:	Low Cost Advanced Personal Communicator (APC)
Abstract:	The goal of the project is to develop an innovative and cost effective technology, that makes the local Common Tactical Picture (CTP) available to warfighters in all echelon theaters through a hands free heads-up display and Windows based computer system. Voice recognition software and touch screen software will serve as the main input devices. By collecting, plotting and updating all warfighter's GPS coordinates, the Common Tactical Picture's Friendly Overlay is updated in real time as echelon shifts take place in the battlefield. Video capturing capabilities aid in providing an integrated tactical picture to all warfighters through virtual data exchange capabilities between Global Command and Control System (GCCS) main CTP who serves as server and Advanced Personal Communicators acting as clients. This relationship will maintain every warfighter's CTP updated. Physiography, political and mission specific feature overlays are generated from Global Command and Control System (GCCS) data sets. Phase I develops the system architecture and demonstrates the feasibility of the proposed techniques. Phase II builds and delivers an engineering prototype system to the Navy.The proposed Low Cost Advanced Personnel Communicator has great potential for use by all branches of the military and real-time information exchange businesses. It provides accurate, updated information, creates a common tactical map and makes mission specific information available when such information is imperative.

CYBERNET SYSTEMS CORP. 727 Airport Boulevard Ann Arbor, MI 48108
Phone: PI: Topic#:	(734) 668-2567 Mr. Joseph Tesar NAVY 01-093 Selected for Award
Title:	Advanced Personal Communicator (APC)
Abstract:	Communication is paramount in nearly all military operations, ranging from tactical operations to the efficient maintenance of equipment. On the battlefront, warfighters are constantly in need of updated information describing the battle zone. To support these warfighters, maintenance personnel need access to a myriad of technical documents and schematics instantly and conveniently. Since maintenance takes place in the field, the maintenance engineer requires display technology that can give him the information he needs in very tight spaces, without causing eyestrain or discomfort. Especially important is a communication device which accesses a central database of information, and that leaves the user's hands free to accomplish other tasks at hand. A device is needed which addresses all of these problems in whole. We propose a system that utilizes modularity to approach the variety of challenges. Modules would consist of display units, input devices, and virtual tools. All would be wireless and interfaced through a Personal Computing Unit, (PCU) which could be worn about the waist, leaving the operative with both hands free.This technology has commercial applications in the areas of flight maintenance and field maintenance. It would also be useful for search and rescue teams, and hazardous waste monitoring and cleanup systems.

GRAMMATECH, INC. 317 N. Aurora Street Ithaca, NY 14850
Phone: PI: Topic#:	(607) 273-7340 Dr. Paul Anderson NAVY 01-094 Selected for Award
Title:	Model Checking UML Designs
Abstract:	Real-time embedded systems are becoming increasingly complex and safety critical. In order to satisfy the complexity and safety requirements developers need tools and methodologies that support rigorous and complete specification capabilities, robust automated translation from design to implementation, support for debugging of the designs at the semantic level of the design specification language, and sophisticated verification and analysis of design models. The Unified Modeling Language and the current generation of COTS tools meet many of these requirements, however they are woefully inadequate in the area of verification and analysis. We plan to augment best-of-breed COTS tools with model checking capabilities. This will not only allow developers to verify their designs, but to also extract greater value from the functionality provided by COTS tools. We propose to integrate model checking with a UML design environment, develop techniques for ensuring scalability and precision, develop a system that allows both everyday and expert users to easily specify properties for verification and develop a system for providing users with insightful counterexamples when their specified properties do not hold.The proposed system will be of use in the design and development of embedded systems. This system will allow companies to develop highly reliable embedded real-time systems.

TIMESYS CORP. 4516 Henry Street, Suite 401 Pittsburgh, PA 15213
Phone: PI: Topic#:	(412) 681-6899 Dr. Manas Saksena NAVY 01-094 Selected for Award
Title:	TimeFrame: A Framework for modeling, analysis, and realization of reliable, object oriented real-time systems
Abstract:	We propose to investigate and prototype an integrated Framework called TimeFrameTM, which shall integrate the modeling, analysis and realization (code generation) of performance critical, reliable, object oriented systems. TimeFrame will utilize UML stereotypes and tagged values and allow modeling of components and interfaces augmented with real-time and reliability specifications. A catalogue facility will enable COTS and custom components/classes to be reused consistently. Using these models, users can generate code targeted towards a standard library, also part of the Framework. The library will consist of (i) standards-based messaging primitives, (ii) distributed resource sets for guaranteed and bounded performance and (iii) interfaces that enable dynamic reconfiguration and active redundant components. Both the code generation and library will be designed for popular languages and platforms thereby supporting a wide variety of projects. In addition, through tight integration with TimeWiz, users will be able to perform performance analysis and generate analysis reports characterizing the ability of the system to meet its deadlines. TimeFrame will also allow specification of custom analysis algorithms of the model to aggregate and extract other reliability and performance aspects. Integration with TimeTrace, TimeQoS and TimeStorm will provide both high-level and low-level debugging and profiling support for the Framework. TimeFrame will be scalable to support a large number of components and provide a visual, hierarchical organization facility.In U.S. defense systems, fly-by-wire avionics, process control, nuclear power control, automated manufacturing, air traffic control and medical systems, life-threatening situations can arise if failures occur due to the misuse of reusable object-oriented software. The TimeFrame framework will maintain, model and analyze the timing and reliability properties of software components and enable the disciplined development and reuse of object-oriented components in the design of such systems.

INFORMATION SYSTEMS LABORATORIES, INC. 8130 Boone Blvd., Suite 500 Vienna, VA 22182
Phone: PI: Topic#:	(703) 448-1116 Dr. Katsumi Ohnishi NAVY 01-095 Selected for Award
Title:	Main Beam Jamming Nulling in Phased Array Radars
Abstract:	A need exists to simultaneously mitigate/cancel interference due to sidelobe and mainlobe jamming and clutter. Practical signal processing techniques with application to existing radars (such as the SPY-1) are required. In this proposal ISL addresses this need by examining two approaches. 1) the use of spatial-only adaptive array processing (followed by Doppler or MTI processing) and 2) space-time adaptive processing (STAP). Each technique will be enhanced by the delta-delta channel, which is currently available but unused on the SPY-1 radar. ISL will explore past related efforts to examine both the spatial and STAP techniques, and compare these techniques in terms of performance and cost/risk of implementation. The spatial-only techniques offer the potential for low-cost, low-risk implementations, however are limited by the number of jammers that can be simultaneously mitigated. STAP offers the potential to simultaneously mitigate a larger numbers of jammers at the cost of increased computational requirements. ISL's site specific radar simulation capabilities will be used extensively in the algorithm development and evaluation.The proposed work will benefit many DoD users requiring advanced interference mitigation technology/algorithms. All shipboard and theater/battlefield array radars (e.g., SPY-1, TPS-59, TPS-70, Patriot, and THAAD) can potentially benefit from this technology as a result of improved robustness to interference and improved target resolution.

INTEGRATED SENSORS, INC. 502 Court St., Suite 210 Utica, NY 13502
Phone: PI: Topic#:	(315) 798-1377 Mr. Walter Szczepanski NAVY 01-095 Selected for Award
Title:	Main Beam Jamming Nulling in Phased Array Radars
Abstract:	Integrated Sensors Inc. and Syracuse Research Corporation propose to develop and demonstrate techniques that effect practical, operationally meaningful, simultaneous mainlobe/sidelobe jamming cancellation in solid state, active array radars while preserving target angular accuracies and permit operation in littoral (clutter) environments. The primary emphasis is: (1) to address phased array radars that do not have access to their subarrays, i.e., only traditional sum, difference, and auxiliary channel availability is assumed, (2) to design an architecture that will effectively suppress simultaneous sidelobe and mainlobe jamming, and (3) to investigate techniques for making the adaptive algorithms compatible with high level, high duty cycle clutter returns in the main beam, as may be expected in the littoral operating environment. Two innovative and promising architectures will be examined: (a) a sequential constrained multiple sidelobe canceler (MSLC)/mainlobe canceler architecture combined with a variant of the Maximum Likelihood Beamspace Processor (MLBP), and (b) a modified MSLC-MLBP adaptation, employing a constrained MSLC and a reduced channel adaptation of the MLBP. Our demonstration plan includes an experimental system including a phased array radar as part of a comprehensive Phase I and Phase II program, eventually leading to implementation of jamming suppression processors for retrofit into existing Navy radars.The technology developed can become an integral part of many future radar system designs for both military and commercial applications. A variety of applications for shipboard, airborne, spaceborne and ground based passive receive systems can significantly benefit as well. Commercial applications for communications systems will also benefit from this technology development.

SCIENTIFIC SYSTEMS CO., INC. 500 West Cummings Park, Suite 3000 Woburn, MA 01801
Phone: PI: Topic#:	(781) 933-5355 Dr. Constantino Rago NAVY 01-096 Selected for Award
Title:	New Non-Cooperative Target Recognition (NCTR) Techniques Development
Abstract:	Scientific Systems Co., Inc. (SSCI) and its subcontractor Lockheed Martin Naval Electronics & Surveillance Systems (LM-NESS) propose to develop an advance simulation framework for High Range Resolution Radar (HRRR) joint target identification and tracking. New techniques for target identification based on HRRR returns, also known as target ``signatures'', will be implemented in this advance simulator. Depending on the illumination angle, different scattering centers on the target are excited, and consequently, the `shape' of the target signature change based on these angles. Therefore, a coupled tracking/identification algorithm should be used in this situation in order to identify a target along an unknown trajectory. Target identification based on HRRR signatures has proven to be a difficult task, due, in part, to the high variability of the signature shape. Signature shape can change dramatically with the aircraft pose angle, and also with the aircraft configuration (addition or change in external ammunition like missiles and bombs). An advance simulation toolbox is needed to evaluate the performance of different identification techniques. The toolbox will include an HRRR simulation, that will allow to model different type of aircrafts, and also to modify the radar parameters (waveform, Signal to Noise Ratio (SNR), and Pulse Repetition Frequency (PRF)). For this effort, SSCI has teamed up with Lockheed-Martin Naval Electronics & Surveillance Systems (LM-NESS), Eagan, MN., who will provide technical support for this effort. Non-cooperative Target Recognition (NCTR) algorithms has a vast field of applications throughout the Navy, including Tactical Ballistic Missile Defense, Ship Self Defense, and Ship Area Defense. Also the Air Force is a potential costumer for this technology. Commercial application of this technology exist in several areas such as: medical screening and diagnosis, remote sensing, road and bridge inspection, and buried waste detection.

TECHNOLOGY SERVICE CORP. 11400 West Olympic Blvd., Suite 300 Los Angeles, CA 90064
Phone: PI: Topic#:	(540) 663-9227 Mr. George LeFurjah NAVY 01-096 Selected for Award
Title:	New Non-Cooperative Target Recognition (NCTR) Techniques Development
Abstract:	To evolve High Range Resolution based NCTR algorithms for application to shipboard TBMD, Self Defense, and Area Defense missions, the Navy surface radar community needs a comprehensive tool that combines detailed target, propagation, and environment models with a flexible coherent radar model. RF signature models, such as Xpatch, can compute the complex frequency, polarization, and aspect angle RCS dependence of targets. Current NCTR development generally involves application of candidate NCTR algorithms against idealized radar signal returns calculated from RCS profiles generated by such models. The limitation of this approach is that it does not account for deviations from an idealized signal return, due to radar errors, propagation effects, and natural and man-made interference. Consequently, their effects must later be evaluated through expensive, yet limited, live target testing. TSC proposes to develop a tool that combines detailed radar and environmental models with complex backscatter modeling. It will integrate TSC's Signal Environment Simulation (SENS) - an existing comprehensive coherent radar model - with existing signature models such as Xpatch, and a six degrees of freedom target trajectory model. This tool will provide effective support for Navy NCTR algorithm development efforts, as well as for predictive or post-test analysis of live target testing.This research and development effort could lead to a unified NCTR development tool capable of modeling all effects from waveform generation and transmission through propagation reflection from the target and reception and signal processing. Such a tool provides a unique capability for design and development of NCTR methods and algorithms, as well as a much needed predictive analysis capability for NAVY testing.

TOYON RESEARCH CORP. Suite A, 75 Aero Camino Goleta, CA 93117
Phone: PI: Topic#:	(805) 968-6787 Mr. Kevin J. Sullivan NAVY 01-096 Selected for Award
Title:	New Non-Cooperative Target Recognition (NCTR) Techniques Development
Abstract:	Toyon Research proposes to develop a non-cooperative target recognition (NCTR) module that classifies airborne targets based on high-range-resolution (HRR) radar measurements collected by any number of sensors over time. The NCTR module will consist of a classifier that uses a representation of the target density function at a number of different aspect angles coupled with a fusion module that can fuse multiple measurements collected over time. The fusion module will consist of a Bayesian Network that updates beliefs about what type of target is being measured by taking into consideration a priori information regarding the types of airborne objects in an area and the capabilities of the sensors providing measurements. Additionally, the network will consider the degree to which a particular measurement matches the expected signal of each type of target of interest. We propose to develop an initial version of the NCTR module and provide a demonstration of its capabilities on an example problem during Phase I.The successful completion of this research will result in the development of an NCTR module that can classify airborne objects using multiple radar measurements collected over time. Non-military applications of this technology include air traffic control, counter-drug operations, and medical diagnostics.

GENERAL SCIENCES, INC. 205 Schoolhouse Road Souderton, PA 18964
Phone: PI: Topic#:	(215) 723-8588 Mr. Anthony Rozanski NAVY 01-097 Selected for Award
Title:	Electrostatic Discharge Analysis of Reactive Material Formulations
Abstract:	Safety assessments of current and future energetic materials require a range of tests, one of which is the determination of the electrostatic discharge (ESD) sensitivity to ignition and propagation. There is currently no standard for circuit design, spark energy, sample size/configuration or determination of a successful test. The need exists for a standard ESD testing machine and related testing methodology to allow accurate and reproducible ESD measurements of energetic materials. The methodology should account for all credible ESD spark sources, such as humans, charged metallic objects (tools) and charged energetic material. In addition to standardizing the ESD machine and methodology, an improved method of determining the energetic materials behavior after an ESD event is required. The proposed detection system is based on an optical method which provides accurate recording of the events leading to material ignition. Both visible and infrared "signatures" emanating from spark to ignition to propagation are recorded in a non-subjective manner. Removal of the human observer, along with the use of a standard detector, will allow for more accurate and reproducible ESD characterization. Upon successful completion of this project, a new testing methodology will have been developed for characterizing an energetic material's electrostatic discharge sensitivity. The new test methodology will be used to design and develop affordable new ESD test equipment to allow accurate, reproducible characterization of an energetic materials' sensitivity to ESD, as well as providing the capability for ESD signature recording for future comparisons. This capability will serve the military as well as the commercial sectors where many accidents can be prevented by more accurate assessments of the ESD sensitivity of reactive materials.

TPL, INC. 3921 Academy Parkway North, NE Albuquerque, NM 87109
Phone: PI: Topic#:	(505) 342-4451 Ms. Catherine Malins NAVY 01-097 Selected for Award
Title:	Electrostatic Discharge Analysis of Reactive Material Formulations
Abstract:	Electrostatic discharge (ESD) sensitivity is critical to understand the safety of energetic materials. ESD ignition of CHNO materials is discernable by a flash, smoke, or audible report. For a small class of reactive materials, e.g., metals and metalloids or metals and binders, the current ESD test methodology is insufficient. TPL proposes to develop an integrated post-dischrge/ESD ignition threshold apparatus. The appartus will determine the extent of the reaction via an analytical technique. These data will be subjected to statistical procedures which will provide insight into the ESD sensitivity and provide applicable data for safety assessment. Candidate materials will be selected and theoretical predictions of the ESD-reacted products will be made. The effects of sample environment will be nulled or baselined as necessary. At least five different analytical techniques will be evaluated for determining the extent of reaction from ESD. An analysis technique will be selected and refined for this application. A preliminary design will be developed. TPL has the resources and the experience to conduct a successful program. The company has outstanding in-house laboratory facilities with machine shop capabilities for prototype or test fixture fabrication. Personnel are familiar with reactive materials, storage, and shipping.The successful completion of this program will provide the Navy with a quantitative method of determining the ESD sensitivity of reactive materials. Better estimates of safety can be made and risk mitigation of hazards will be more accurately determined.

AMERICAN GNC CORP. 888 Easy Street Simi Valley, CA 93065
Phone: PI: Topic#:	(805) 582-0582 Dr. Ching-Fang Lin NAVY 01-098 Selected for Award
Title:	A Software Based Navigation Agent (NavAgent) Tool for Navigation Systems Integration
Abstract:	This project develops an innovative navigation agent software tool, integrated with standards based information management platform, that would simplify the task of NavInfo integration with shipboard navigation and weapons systems networks and that would significant reduce the cost of managing these systems. The tool would allow the definition of Navigation Agents (NavAgents) that would adapt the information needs of a new system into an existing infrastructure. The NavAgents could be defined either by a system itself or by an administrator through a network management console. This allows maximum flexibility while not necessarily requiring that the new system support NavAgents directly. Each NavAgent could be defined for selective processing and mixing of the any NavInfo being integrated. The NavAgent on the network management console would serve as a very powerful tool for solving interfacing problems during installation and integration as well for normal ship's maintenance. The activities of NavAgents could be trapped to a file for later analysis or playback. This allows the interfacing problems to be easily isolated, diagnosed, and resolved.The proposed navigation agent software tool has great potential applications for military and commercial aircraft, space vehicles and ships. It provides reliable, robust, and convenient navigation integration tool.

SYNETICS, INC. 555 Edgewater Drive, Third Floor Wakefield, MA 01880
Phone: PI: Topic#:	(540) 663-2137 Mr. Stephen Goss NAVY 01-098 Selected for Award
Title:	A Navigation Agent (NavAgent) Tool for Shipboard Navigation & Weapons Systems Integration
Abstract:	Through the years, the Navy has seen advances in navigation technology flow through their tactical navigation systems. These include the AN/WSN-5, AN/WSN-7, NAVSSI, and GPS. With each navigation system enhancement came more accurate, precise, and complete navigation information at higher and higher data rates, culminating in today's ability to maintain high accuracy (even in jamming), provide for a single shipwide navigation solution, utilize and synthesize multiple navigational sub-systems, and, provide operational availability in excess of 99%. However, the engineering efforts that have been performed and applied within the navigation problem domain, have not been applied when addressing how the entire navigation system might provide its information to those "other systems" requiring it. The Navy is still using point-to-point interfaces and outdated MIL-STDs, which almost never document "those unique intricacies" of how information data interchange really work. Using current technologies that include HTTP, eXtensible Markup Language (XML), and Simple Object Access Protocol (SOAP), Synetics proposes to establish a Computer Aided Agent Development and Execution Environment (CAADEE) from which Information Interchange Agents (IIAs) can be constructed, configured, spawned, monitored, and controlled. The IIAs would be capable of attaching themselves to the specific systems and handling their data interchange needs.Although CAADEE would be initially targeted to support the needs of the navigation problem domain, its design would be capable of supporting the configuration, construction, spawning, monitoring, and controlling of IIAs for other problem domains. This capability allows CAADEE and its IIAs to be applied to a myriad of DoD system and system-of-system engineering and development efforts. The commercial market space has similar needs regarding information interchange. For instance, the business commerce community is pushing Business-to-Business e-commerce, which is nothing more than the exchange of data between businesses. CAADEE and its IIAs could meet this need as well.

CENTER FOR REMOTE SENSING, INC. 11350 Random Hills Rd., Suite 710 Fairfax, VA 22030
Phone: PI: Topic#:	(703) 385-7717 Dr. Suman Ganguly NAVY 01-099 Selected for Award
Title:	Environmentally Adaptive Radar
Abstract:	This proposal describes a plan to develop radar systems which will adapt the radar parameters in order to optimize the performance under different environmental conditions. Environmental data will be collected from various sensors including those available from the radar echoes. These data will first be used to create as complete a picture of the environment as possible. Next, the radar parameters will be selected based on the optimum conditions under these environments. An expert system will be developed to synthesize the environmental conditions and to predict the radar parameters. Design, development and demonstration of the expert system is the major task during Phase I. Extensive simulations will be performed in order to develop the expert system and for demonstration of the improvements of the radar performance using the expert system. Detailed development and demonstration using real data available from radars will be performed during Phase II. Adaptive radars will improve the performance of a variety of military and non-military radars and will have widespread applications as add-ons to existing radar systems.

TECHNOLOGY SERVICE CORP. 11400 West Olympic Blvd., Suite 300 Los Angeles, CA 90064
Phone: PI: Topic#:	(301) 565-2770 Dr. Menachem Levitas NAVY 01-099 Selected for Award
Title:	Utilization of Atmospheric Refractivity Information to Improve Radar Operation in Littoral Environments
Abstract:	Atmospheric refractivity conditions have significant influence over radio frequency (RF) propagation in the Earth's troposphere. Refractivity conditions can vary from sub-refraction to strong-trapping, thereby altering radar detection, measurement, and clutter performance across its coverage volume. Current Navy radar systems operate without regard to changing refractivity conditions, mainly because quantitative descriptions of such conditions have not been generally available to operational systems and could not be converted to their propagation performance equivalent in near-real-time. Recent advances in the areas of refractivity estimation from basic parameter measurements and from clutter measurements, coupled with improvements in the processing efficiency of Parabolic-Equation-based propagation models, can narrow that gap. This proposal identifies applications for ship-based radars, such as the AN/SPY-1 family, whose performance could be enhanced through judicious utilization of refractivity information. It describes architecture and techniques to combine information from linear, high-resolution, clutter-maps, with information from propagation-coverage-maps, to improve radar performance in detection, tracking, engagement, and resource conservation, and to further extend the utilization of such information to improve radar sensor fusion and combat system performance. Specific techniques to be analyzed in detail during the Phase I base-period in order to establish their feasibility are described - each with its corresponding technical approach.This research and development effort could lead to clear understanding of shipboard sensor applications whose performance could be enhanced via judicious use of combined propagation and clutter information, and of the processing architecture and processing algorithms required to support such improvements. It could be used to enhance the performance of new fleet sensors and combat systems via appropriate design, and of legacy systems through upgrades. A proposed software analysis package, which will contain pertinent architectural elements, will be marketed to potential radar and radar upgrade developers, in support of specific algorithm developments.

DIGITAL SYSTEM RESOURCES, INC. 12450 Fair Lakes Circle, Suite 500 Fairfax, VA 22033
Phone: PI: Topic#:	(703) 263-2824 Mr. Joseph Lucas NAVY 01-100 Selected for Award
Title:	Mission Planning for Tactical Shipboard EW Systems
Abstract:	DSR proposes development of a methodology for the utilization of information from mission objectives and a wide variety of platform, sensor and intelligence databases to effectively adapt tactical shipboard sensor resources to a dynamically changing tactical environment and to increase the time available to develop appropriate responses to changes in the tactical environment.The overall objective of the proposed research is for Digital System Resources, working closely with Navy fleet representatives, to establish and validate a baseline understanding of the current Navy EW mission planning concept of operations, associated requirements, data sources dependencies, and existing system capabilities. The result of this research is intended to form the basis for successful execution of development and production of an EW mission planning component applicable to both current and future Electronic Warfare Systems. Specifically, the results will identify methods to allow the user to visualize the anticipated environment and allow for adaptation of system resources based on the intelligence gathered.Provide mission planning requirements and prototype mission planning displays. The Phase II plan will specifically target integrating the approach into a state-of-the-art system for demonstration. Potential commercial applications for situation awareness visualization techniques, integrated database analysis tools and tools that allow the user to develop rules to optimize system resources.

INTELLIGENT SYSTEMS TECHNOLOGY, INC. 2800 28th Street, Suite 306 Santa Monica, CA 90405
Phone: PI: Topic#:	(310) 581-5440 Dr. Azad M. Madni NAVY 01-101 Selected for Award
Title:	MainTrain: Maintenance Skills Training Through Distributed Learning Principles
Abstract:	Maintenance and technical skills training is required to build individual proficiency within the U.S. Navy battle groups as well as many of the independent operating units. However, force reduction and budget cutbacks have resulted in the transfer of training responsibility for battle groups to the large deck ship and battle force commanders. With further reductions in force levels and budget on the horizon, the Navy has to turn to harnessing distributed learning principles, remote maintenance skills training, and maintenance support in a web-based delivery environment. Phase I of this effort will create the system concept and design documents for a web-enabled interactive mentoring system and an instructional content sharing and management system, the two core components of MainTrain, a web-based maintenance instructional delivery and troubleshooting support system.NAVSEA O4L will directly benefit from this technology by having a maintenance crew cost-effectively trained despite force reduction and budgetary cuts. The commercial version of this system will offer cost-effective, realtime assistance to maintenance field personnel engaged in equipment and machinery repair in remote field locations. The avoidance of travel costs and satisfying time-criticality requirements are key to acceptance of this solution in the commercial world.

BMA ENGINEERING, INC. 11429 Palatine Drive Potomac, MD 20854
Phone: PI: Topic#:	(301) 299-9375 Dr. Bilal M. Ayyub NAVY 01-102 Selected for Award
Title:	Risk-Based Maintenance Strategies to Reduce Total Ownership Costs
Abstract:	The objective of Phase I is to develop a practical methodology and procedure for implementing risk in the decision-making process for structural maintenance and repair. The specific tasks needed to achieve these objectives of the proposed effort can be enumerated as follows: 1. Assessment of Existing Maintenance Strategies for Ship Structures that includes � Assessment of inspection and maintenance strategies in ship structures � Assessment of risk methods � Assessment of total ownership costs 2. Development of Risk-Based Maintenance Strategies for Ship Structures that includes � Development of a plan to utilize experience, engineering judgment, historical data and expert opinion in identification of critical damage modes and sites for selected ship categories � Development of methods for estimating qualitative risk measures at critical locations using event trees � Development of methods for screening and ranking of critical locations � Development of methods for estimating quantitative risk measures at selected critical locations using probabilistic reliability methods and event trees 3. Development of a plan to Utilize Risk Measures for Optimal Planning of Inspections and Maintenance Schedules that includes � Development of models for updating inspection and maintenance plans � Development of a plan for a risk-based maintenance software tool 4. Definition of Software Requirements that includes � Preliminary design of software tool � Demonstration of proposed methodology 5. Demonstration of Methodology for Typical Ship Details that includes � Demonstration of software plan 6. Optional Effort: Definition of Software Requirements, and Prototype Risk Based Management Tool. 7. Development of a plan for Phase II that includes refinement of methodology for software architecture, development of software tool, incorporation of existing guidelines, and demonstration on ship structures. The marine industry needs assistance in managing inspection and maintenance activities in a manner to reduce total ownership cost. There is a need to efficiently identify critical maintenance locations and perform appropriate repairs and fixes. The anticipated products from this SBIR effort are in the form of risk-based maintenance strategies to reduce total ownership costs, and software that would help in meeting the needs of the industry.

SOHAR, INC. 8421 Wilshire Boulevard, Suite 201 Beverly Hills, CA 90211
Phone: PI: Topic#:	(323) 653-4717 Mr. Myron Hecht NAVY 01-102 Selected for Award
Title:	A Tool for Risk-Based Maintenance and Inspection of the LPD 17
Abstract:	Risk-based methods for inspection and maintenance can significantly reduce lifecycle cost by basing inspection and repair intervals on the risk of incurring damage rather than on arbitrary periods. Not only can the methods reduce inspection cost and downtime, they can actually increase ship reliability and safety by defining explicit failure probabilities for all important components and functions. SoHaR and its subcontractor, EQE/ABS (a part of the American Bureau of Shipping), propose to develop a Risk Based Maintenance Strategy Tool (RBMST) to support a risk-based maintenance approach for the LPD 17. The innovations of our approach include the use of a probabilistic fracture mechanics model as opposed to the traditional SN curves. The benefit of a probabilistic model is that it yields a failure probability rather than an expected life. The RBMST will also integrate corrosion and fracture fatigue mechanisms in a single model, account for previous repair history, and incorporate cost and safety. The model uses a conditional probability approach to account for past maintenance and repair actions. A prototype tool using the Matlab program will be delivered at the end of Phase I. The prototype will include sophisticated modeling capabilities, results plotting, and a graphical user interface. The team members combine a unique combination of expertise in probabilistic methods and domain expertise in marine and ship structures that will ensure project success.Risk based maintenance is becoming increasingly important in all aspects of the marine and offshore technology industries. The benefits relative to fixed periodic maintenance programs are lower downtime and decreased inspection costs. The probabilistic fracture mechanics approach that is being used in the RBMST provides a significant advantage over the traditional engineering "design rule" approach that is based on SN curves and predicted life. RBMST permits a comprehensive and detailed risk-based maintenance and inspection approach to be implemented. In its full implementation RBMST will be able to calculate all static and dynamic loads, predict condition into the future based on the probabilistic techniques, and provide a visual representation of the results.

IMAGE ACOUSTICS, INC. 97 Elm Street Cohasset, MA 02025
Phone: PI: Topic#:	(781) 383-2002 Dr. John L. Butler NAVY 01-103 Awarded: 30APR01
Title:	Ultra Wideband Active Acoustic Conformal Array Module
Abstract:	An ultra wideband conformal array module will be developed and designed for use on submarines. The band of interest is 10 to 85 kHz with a 450 steering capability without grating lobe structure. A power density of 11 watts/cm2 over the frequency band is desired. The goal is to include the transducer elements, T/R switch, power amplifiers and receive preamplifiers in the module. We consider the ultra wideband transducer with steering requirements to be the most challenging aspect and the one which requires advance innovative concepts for a practical solution. We propose to consider the use of high power density materials to obtain the output, a multiple resonant system to obtain the bandwidth and a multiple actuated piston head to obtain the desired steering even at the highest frequencies, along with array stability at the lowest frequencies. The transducers would be made as small as practical to allow the packaging of the electronics within the module. Extensive circuit analysis, array analysis and finite element modeling would be used to optimize the design.An ultra wideband steerable transducer module will be designed for submarine applications. The multi-resonant, multi-actuated piston design chosen should provide an approach applicable to current and future underwater acoustic systems. The technology should provide a significant improvement for high frequency sonar systems, and possibly for oceanographic and ultrasonic imaging systems.

MATERIALS SYSTEMS, INC. 521 Great Road Littleton, MA 01460
Phone: PI: Topic#:	(978) 486-0404 Mr. Alan Curtis NAVY 01-103 Selected for Award
Title:	Wideband Conformal Transducer Array Module
Abstract:	MSI proposes the development of a sonar array module that has a very wide bandwidth and can support a range of array configurations including conforming to a curved hull structure. The MSI design will be built around piezoelectric ceramic/polymer composite, a proven transducer material with inherent advantages that is finding ever-wider application in broad band sonar systems. The transmit array will be electronically beam steerable. Outboard receive signal processing, muxing, and telemetry electronics will be integrated within the array module along with drive electronics for the transmit array, so that the only hull penetration requirements will be for DC power and data telemetry. In Phase I, MSI will conduct a design study to determine the feasibility of making an affordable modular conformal projector array that meets functionality specifications for the intended Navy application. In Phase II, MSI will perform build and test prototype array iterations and demonstrate that the final design meets performance, cost, environmental and configuration requirements for Navy use. In Phase III, MSI will establish a business relationship with appropriate platform and sonar systems integration contractors to transition the modules to production and will then produce the modules to meet Navy deployment requirements The proposed program will enable the navy to meet a specific platform sonar requirement. The technology developed during the program will have applicability to all Navy and commercial platforms, both surface and subsurface, that operate in the RFP specified frequency ranges. This includes defense and commercial markets in which MSI already participates as a transducer array vendor.

RD INSTRUMENTS 9855 Businesspark Ave. San Deigo, CA 92131
Phone: PI: Topic#:	(858) 693-1178 Dr. Joel Young NAVY 01-104 Selected for Award
Title:	Underwater Velocity Indicator
Abstract:	The Navy has a need for an Underwater Velocity Indicator which can be mounted on a submersible platform and which can measure the three-component velocity of the platform relative to the water at speeds up to 40 kts. The Acoustic Doppler Current Profiler (ADCP) can provide this capability. These instruments can measure the three-component velocity vector of the water relative to the platform on which they are mounted at a sequence of ranges from the transducer face. This well established acoustic technology is the most reliable and robust way of meeting the Navy's requirement for a compact saltwater velocity indicator system which can be calibrated and mounted easily on a submersible platform. Present ADCPs, however, are limited to speeds lower than 40 kts. by their processing capabilities and their physical configurations. Phase I will consist of reviewing the Navy's requirements and adapting an ADCP to meet them. We will consider both conventional and phased array transducers as well as existing and developmental electronic implementations of this new, High Speed Underwater Velocity Indicator. We will provide a prototype instrument for testing by the Navy in Phase I.The High Speed Underwater Velocity Indicator will extend the use of ADCPs to high speed platforms, both military and commercial. This includes undersea vehicles and surface vessels such as patrol craft and ferries. It will also find application in industrial facilities requiring cost effective flow measurement data.

TAO OF SYSTEMS INTEGRATION, INC. 471 McLaws Circle, Suite 1 Williamsburg, VA 23185
Phone: PI: Topic#:	(757) 220-5040 Dr. Siva Mangalam NAVY 01-104 Selected for Award
Title:	Accurate, Large Bandwidth Underwater Speed and Flow-Angularity Measurement Device
Abstract:	A miniaturized, low power and low-volume instrumentation system using waterproofed micro-thin hot-film sensors and large bandwidth constant voltage anemometer will be developed for accurate measurement of speed and direction of underwater vehicles. The performance of the proposed innovation will be unaffected by changes in ambient temperatures, depth, and salinity. Sensors will be waterproofed to protect them from corrosive effects of marine environment. The device will have a large built-in redundancy and the design will permit a relatively straightforward handling of biofouling. The proposed innovation is based on flow characteristics and thereby eliminates inherent disadvantages present in conventional techniques based on fluid properties. The proposed innovation will be practically immune to EMI, RFI, and drift. Both the probe and the electronic instrumentation system will be amenable to miniaturization. The weight of the sensor will be negligible while the instrumentation weight will be reduced to a few grams with the use of flexible circuits, with corresponding decrease in power requirements. In Phase I effort, a number of probe-design configurations will be tested in Tao Systems' high-speed water tunnel to demonstrate the feasibility, accuracy and repeatability of the innovation. Velocity indicator can be used for commercial marine vehicles or in industrial facilities requiring cost-effective flow measurement data.

PHYSICAL SCIENCES, INC. 20 New England Business Center Andover, MA 01810
Phone: PI: Topic#:	(978) 689-0003 Dr. Peter E. Nebolsine NAVY 01-105 Selected for Award
Title:	All Optical Towed Array Position Measurement System
Abstract:	Physical Sciences Inc.(PSI) proposes to develop a fiber optic position measurement system for multi-line towed array applications. PSI's proprietary approach for fiber optic position measurement system sources and receivers will meet the requirements of the solicitation each with a very compact package size, nominally 0.5 inch diameter and no longer than 5 inches. George Connolly, MTI, will assist PSI, validating PMS source requirements and then PSI will complete the design of proof of principle configurations for at least two different concepts. These proof of concept designs will be initially tested in the laboratory and then at NUWC's Dodge Pond demonstrating proof of principle operation and that the requirements can be met by PSI's innovative approach. A Phase II program plan will be developed that when performed in a Phase II program, will result in a complete demonstration of the key technologies and components of the fiber optic position measurement system necessary for prototype development. The Phase I Option would be the detailed design of the Phase II system.The proposed program will develop a fiber optic position measurement system, which is an enabling technology for all-optical towed arrays. Such arrays for both DoD and commercial applications, e.g., seismic oil exploration, have the potential of reduced costs, increased reliability, and improved performance.

FOSTER-MILLER, INC. 350 Second Ave. Waltham, MA 02451
Phone: PI: Topic#:	(781) 684-4423 Mr. William Posage NAVY 01-106 Selected for Award
Title:	Application of NDE Techniques for In-Situ Inspection of Submarine Propellor Shafts
Abstract:	Although no one technology solves all the inspection issues peculiar to submarine propeller shafts, a combination of long range ultrasonic techniques succeed where single approaches fail. One method we will use emits a pulse of refracted shear waves that interact with indications in the material, causing a signal to be reflected back to the transducer. Another method generates refracted broad beam longitudinal waves that diffract off discontinuities resulting in a signal that is detected by a second, discrete receiver. Experiments using a calibrated defect specimen will demonstrate that these two methods can detect deep flaws and surface corrosion in the base material, pitting in the FRP wrap, and discontinuities in the bond. Fixtures for the transducers allowing for inspection of the curved propeller shaft and a data reduction algorithm that removes much of ambiguous noise that stymie other techniques, will be key features of our approach. Our program will produce a conceptual design for a deployable prototype system for fabrication and test in Phase II. Foster-Miller has teamed with the world's premier submarine builder, and an internationally recognized NDE development firm to present the best in submarine technology, materials and NDE knowledge, and implementation and integration skill available anywhere. (P-01383) The combination a variety of long range ultrasonic techniques succeed in detecting corrosion and wear indications on propeller shafts where single approaches fail. Early detection of these flaws stand to save the Navy millions of dollars in direct propeller shaft inspection and nuclear asset utilization over the course of just a few years. The technology is directly applicable to other Navy ships and commercial fleets as well. Off the shelf technology will be used extensively to ensure that additional systems will be inexpensive to procure in the event that the technology is implemented fleet wide.

TEXAS RESEARCH INSTITUTE AUSTIN, INC. 9063 Bee Caves Road Austin, TX 78733
Phone: PI: Topic#:	(512) 263-2101 Dr. Michael L. Dingus NAVY 01-106 Selected for Award
Title:	Propulsion Shaft Interrogation
Abstract:	The Navy currently employs a time-based maintenance schedule for its submarine propulsion shafts, in which every 6 or 10 years each shaft aboard the submarine is removed from service, stripped of its protective FRP layer, and inspected for cracks and wall-thinning with magnetic particle and liquid penetrant inspection methods. This represents an expensive investment of time, money and effort on the part of the Navy, but is currently the only proven method of maintaining the readiness of the fleet. TRI/Austin proposes that the Navy shift focus to a condition-based maintenance schedule through funding a research and development effort to build a multi-diameter in-line ultrasonic inspection tool that inspects the propulsion shaft by removing the propeller and inspecting from the inside. This approach allows the tool to inspect the shaft regardless of whether it is in F-, M-, or A-Condition. The TRI/Austin team's experience in developing commercial multi-diameter in-line inspection tools, coupled with our triple-redundancy inspection system design, assures complete and total inspection of the entire propulsion shaft and represents a tremendous opportunity in terms of reducing the Navy's cost of ownership and operation of the submarine fleet.Propulsion shafts find widespread use throughout all the vessels in the U.S. Naval fleets, those of her allies, and commercial marine vessels. Our innovative tool design can save millions of dollars world-wide through its adaptation to other propulsion shaft designs. We also anticipate a strong response for a multi-diameter in-line tool in the oil and gas industry, nuclear reactor piping in which the pipes are typically thick-walled, and potentially through the inspection of terrestrial drive shafts. Our aggressive technology transfer work is designed to target these and other opportunities towards full commercial development.

AF - 368 Phase I Selections from the 01.1 Solicitation

---------- AF ----------

368 Phase I Selections from the 01.1 Solicitation

(In Topic Number Order)

PHYSICAL SCIENCES, INC. 20 New England Business Center Andover, MA 01810
Phone: PI: Topic#:	(978) 689-0003 Dr. Steven J. Davis AF 01-001 Awarded: 27APR01
Title:	Advanced Concepts for the Chemical Oxygen-Iodine Laser
Abstract:	Physical Sciences Inc. (PSI) proposes to investigate and demonstrate the feasibility of two enabling technologies to radically improve the chemical efficiency of chemical oxygen iodine lasers (COILs). We propose to examine three potential methods for producing flows of atomic iodine that would reduce or eliminate the amount of singlet delta oxygen required to dissociate the molecular iodine in current COIL devices. PSI proposes to use existing state-of-the-art facilities and techniques to investigate two photolysis methods and one chemical method for dissociating the iodine. One of the photolysis methods has the potential for allowing premixing of the iodine source with the singlet oxygen stream. This has the potential for reducing the complexity or even eliminating mixing nozzles in COIL. PSI also proposes to test the feasibility of a high power microwave driven plasma jet (MIDJet) as a source of excited singlet oxygen. This aspect of our Phase I effort will complement current programs elsewhere that are attempting to develop an electric COIL. A successful program would demonstrate the feasibility of dramatically improving the performance of COIL devices. This could offer new important missions for the Air Force. New commercial applications of COIL devices that would become logistically and financially much more attractive include: laser welding, hole drilling, nuclear power plant dismantling, and gas/oil well drilling.

SCIENTIFIC APPLICATIONS & RESEARCH 15261 Connector Lane Huntington Beach, CA 92649
Phone: PI: Topic#:	(714) 903-1000 Mr. John Dering AF 01-001 Awarded: 25APR01
Title:	Advanced Concepts for the Chemical Oxygen-Iodine Laser
Abstract:	System weight and volume are critical aspects that determine the Airborne Laser (ABL) platform operating altitude, total laser run time and aircraft refueling requirements. While COIL technology has made significant strides in system efficiency increases, an overall system weight reduction is needed. SARA, Inc. proposes a highly, innovative RF transmission line plasma technique to pre-dissociate molecular Iodine into free Iodine atoms before interaction with Singlet Delta Oxygen. Singlet Delta Oxygen is the energy storage and pump species that collisionally excites atomic iodine to the upper lasing state for the high energy 1.3mm laser airborne weapon output. Ideally one singlet delta collision results in one excited iodine atom and thus laser photon. In addition, the singlet delta flow must also first perform the requisite prior step of collisional disso-ciation of the molecular iodine (I2) into two iodine atoms (I-atoms). The dissociation process is not efficient with 2 to 3 singlet delta species required to dissociate one iodine molecule. SARA's RF plasma dissociation technique will allow more Singlet Delta Oxygen to be used to collisionaly excite the iodine, increasing the laser power output and reducing the number of laser modules required for the ABL mission. This technique will result in an increase in laser power output over the existing ABL design for the same BHP and reactant consumption rates. The power increase would allow for a decrease in ABL system weight by reducing the total number of laser module building blocks required. All other COIL applications would benefit by the increased utilization of singlet delta oxygen, providing a potential expanding market.

STI OPTRONICS 2755 Northup Way Bellevue, WA 98004
Phone: PI: Topic#:	(425) 827-0460 Dr. William Thayer, III AF 01-001 Awarded: 27APR01
Title:	Singlet Oxygen Generator Design For Advanced COIL With Water Vapor Control
Abstract:	Chemical oxygen iodine lasers are efficient, scalable, and have proven ability in generating weapons class laser power. To support the future high power COIL programs, technology improvements must be realized to more easily meet the operational requirements, such as for the ABL EDM phase. In particular the SOG performance with mixed base BHP must be augmented to allow operation through a wider molarity range and at higher BHP temperature to reduce magazine size and weight. Innovative methods for improving the COIL efficiency by increasing singlet oxygen output, reducing singlet oxygen losses, removing water vapor, and reducing liquid carryover from the SOG will further improve high power COIL performance. The proposed Phase I program will build on the knowledge gained at STI to evaluate several innovative concepts and design an optimized water vapor trap, spray separator, and sidewall liquid control configuration that will eliminate carryover and maximize the SOG performance. Using the SOG development code developed by STI, we will investigate the design trade between two candidate WVC fluids and the geometry changes required to package the system. Additionally, the Phase II program will be developed with the aim of proof of principal experiments to verify the design concepts. COIL is an attractive option for an industrial laser due to short wavelength and ability to be transmitted by fiber optic. Some potential industrial applications are shipbuilding, automotive manufacturing, heavy machinery manufacturing, tasks requiring underwater cutting or welding, and there may be useful applications in the oil and gas industry. It is possible to envision a single high-power COIL feeding many fibers for industrial cutting/welding/processing application. Fiber delivered underwater applications appear very promising; it may be possible to use a high power, fiber delivered COIL beam to perform cutting/welding underwater and thus save the high cost of dry-docking a ship in need of repair. However, the primary market for COIL is defense related. Consequently STI has concentrated its efforts in the development of high performance SOGs primarily for defense applications, advancing the state of the art to the benefit of both military and commercial applications.

TEMPEST TECHNOLOGIES LLC 2916 Stanford Avenue Marina del Rey, CA 90292
Phone: PI: Topic#:	(310) 574-4993 Dr. Ben Fitzpatrick AF 01-002 Awarded: 25APR01
Title:	Wavefront Sensing for High Scintillation Environments
Abstract:	In this proposal we consider the incorporation of image processing techniques into phase reconstruction algorithms to improve performance in systems such as the AirBorne Laser (ABL) tactical missile defense system. Based on a combination of mathematical techniques for nonparametric branch cut identification and adaptive filtering theory, our methods promise to provide greatly enhanced phase estimation. Scintillation, the turbulence-induced fluctuation of image intensities, is widely regarded as a major problem for adaptive optics systems. The methods we propose herein provide the potential to mitigate significantly the effects of scintillation, thus enhancing adaptive optics performance. We also propose innovative control concepts for deformable mirror actuation. Collaborating with scientists and engineers at UCLA, MZA, AFRL, and Boeing-SVS, we will use wave propagation simulations data and data collected in tests at Lincoln Laboratory's ACL facility to score the performance of these algorithms. Continuing our partnership with Boeing-SVS, the leader in systems engineering for optical systems for ABL and other weapon systems, will allow us to leverage the results obtained in this effort into hardware systems in a most efficient and cost-effective manner. Potential commercial applications will be of a military nature, as the effort proposed herein is heavily focused toward advancing ABL system capabilities. Other phase-based imaging systems, such as SAR and MRI, will benefit, however, from improvements derived from this research.

TREX ENTERPRISES CORP. 10455 Pacific Center Court San Diego, CA 92121
Phone: PI: Topic#:	(858) 646-5479 Dr. Mikhail Belen'kii AF 01-002 Awarded: 12APR01
Title:	Wavefront Sensing for High Scintillation Environments
Abstract:	Strong scintillation in long horizontal path laser beam projection systems, such as ABL, corrupts the phase difference measurements made with a Hartmann sensor by causing non-uniform illumination of the sub-apertures, hence, non-uniform noise effects across the wave front sensor. Strong scintillation can also cause branch points in the beacon field making the wave front reconstruction and correction processes difficult because they lack the continuous phase map required in most wave front correction schemes. We propose a shearing interferometer wavefront sensor and a new wavefront reconstruction algorithm insensitive to the branch points. Our new approach will provide accurate phase recovery in a high scintillation environment. Phase I develops a simulation code and reconstruction algorithm and evaluates the performance of this innovative technique. We expect a detailed simulation code for the static shearing interferometer and a new phase reconstruction algorithm will be developed and the feasibility of the proposed approach will be evaluated for various ABL propagation scenarios in high scintillation environment. This effort heralds development of a new wavefront sensing capability which will enable expansion of ABL missions for longer range and lower elevation operations and forms a basis for commercial wavefront sensors for laser communication systems. The proposed scintillation resistant wavefront sensor and reconstructor have both military and commercial applications. Besides the ABL, a static shearing interferometer can also be used in Relay Mirror, remote sensing and atmospheric imaging programs. A shearing interferometer wavefront sensor proposed here may also result in significant improvements in the performance of active ground-based satellite imaging systems. The proposed approach can also lead to the development of a commercial wavefront sensor. This sensor would be used in commercial low-order AO systems to mitigate atmospheric effects in high data rate optical communication channels. A shearing interferometer developed under this program can be a key element in this system.

MZA ASSOC. CORP. 2021 Girard SE, Suite 150 Albuquerque, NM 87106
Phone: PI: Topic#:	(505) 245-9970 Mr. Stephen C. Coy AF 01-003 Awarded: 12APR01
Title:	Multiconjugate Adaptive Optics for Distributed Turbulence
Abstract:	Conventional aperture plane phase-only adaptive optics (AO) is becoming a mature technology. We have had decades of experience with up-looking applications, where most of the turbulence is close to the aperture, and in recent years there has been substantial progress in AO for near-horizontal paths, with distributed turbulence, largely motivated by the Airborne Laser (ABL) Program. Progress continues, but the practical limits of conventional AO technology for deep turbulence applications are beginning to become apparent. These relate to scintillation, high order anisoplanatism, phase branch points, and the use uncooperative beacons for tracking and higher order correction under conditions where these effects are prevalent. Conventional AO does not address scintillation or high order anisoplanatism at all, and branch points present serious practical difficulties even when perfect sensing is assumed. Multiconjugate (MCAO adaptive optics is a less developed technology involving significant technical challenges, but there are reasons to believe it may be able to ameliorate these problems, yielding improved performance over a wide range of conditions, and, more importantly, yielding acceptable performance in regimes where conventional AO fails. For the ABL this would translate into a longer maximum range, and killing missiles that otherwise would have gotten past.It is anticipated that a multiple deformable mirror adaptive optics system successfully demonstrated under this research, with economical considerations folded in, would have both commercial and military applications. The military applications include the ABL and follow-on systems, Relay Mirror, remote sensing, and any DoD programs utilizing adaptive optics in high scintillation. Other applications include airborne imaging (military and commercial), especially for reconnaissance and surveillance systems that must image through turbulent boundary layers. The commercial market includes such areas as astronomy (retrofitting astronomical sites), laser communication and power beaming. It is expected that the contractor will focus on Phase I designs that would maximize both the commercial potential and the military potential.

OPTICAL PHYSICS CO. 4505 Las Virgenes Road, Suite 217 Calabasas, CA 91302
Phone: PI: Topic#:	(818) 871-1841 Dr. Richard Hutchin AF 01-003 Awarded: 07MAR01
Title:	3D WAVEFRONT CONTROL
Abstract:	A new control concept is proposed which can significantly enhance the performance of the Airborne Laser beam control. This control process allows high quality wavefront information to be obtained even using extended sources of many theta-noughts in size. In simulation, a simple version increased high-order strehl 1.67X and on-axis irradiance by 5.7X over a 120 km horizontal path with a 1mx1m extended source. Besides the major benefit to the ABL program, there is another commercial application. The Last-Mile Optical Link involves high bandwidth laser communication over near-ground horizontal paths up to 5 kilometers long. With DWDM (Dense Wavelength Division Multiplexing), the need is to image a first fiber source onto a second fiber receiver several kilometers away. Optical efficiency requires a high strehl to avoid fades and resulting data loss. This sensor will greatly increase reliability.

METROLASER, INC. 18010 Skypark Circle, Suite 100 Irvine, CA 92614
Phone: PI: Topic#:	(949) 553-0688 Dr. Vladimir Markov AF 01-004 Awarded: 01MAR01
Title:	Laser System for Active Tracking of a Launch Vehicle and Satellite
Abstract:	In this Phase I proposal, we outline a plan to develop a novel phase-conjugate laser system capable of locking and tracking remote objects. The proposed system uses a pulsed laser with an intra-cavity four-wave mixing configuration. In this proposal, we outline the operational principles of the system, showing how velocity and position of the target can be accurately measured. During Phase I, we will perform additional theoretical analysis, design a laboratory system, and demonstrate the key aspects of the tracking system. During Phase II we will scale the technology up for field demonstration.Optical systems can provide precise information on an object's location and velocity. The proposed system can significantly enhance the accuracy of existing radar-based tracking stations. Because of the increased measurement accuracy, measurements of satellites can be performed less frequently and with fewer tracking stations, thus saving on operational costs. In addition, the system could find applications in aircraft and missile tracking.

PC PHOTONICS 64 Windward Way Waterford, CT 06385
Phone: PI: Topic#:	(860) 443-4356 Dr. George G. King AF 01-005 Awarded: 06APR01
Title:	Key Enabling Components for High-Power Fiber Lasers
Abstract:	Three key enabling components are critically needed for advancing high power fiber lasers. They are the double clad, multicore fibers; high brightness diode laser pumps; and optical coupling between the pump and the fiber. This proposal is focused on the most neglected component, the coupling between the pump and fiber laser. Material damage thresholds eliminate end pumping as a viable way to achieve multiple kilowatt outputs from a double clad fiber laser system. Side pumping the entire surface of a double clad system has not shown promise due to excessive losses that are artifacts inherent in the design. The aim of this proposal is to develop a reliable optical coupling technique by distributing the pump power at various strategic locations along the length of the double clad fiber without compromising the fiber integrity. The design of our proposed coupling scheme takes into account the effective absorption of the fiber cores along the propagation length of the fiber. The pump power from a multimode fiber is injected into the inner cladding at an angle exceeding the critical angle. With this approach it may be possible to couple several kilowatts of pump power into the fiber without exceeding the material damage threshold. This proposal describes an approach and presents the necessary steps to demonstrate the practicality of our proposed coupling scheme. If the results of this Phase I prove successful a Phase II will be proposed to develop a prototype which will be delivered to the Air Force for demonstration. High power diode-pumped multicore fiber lasers can be very competitive in the market place as compared to high power diode-pumped solid-state lasers and C02 lasers presently employed by automotive, aerospace and ship-building industries for precision drilling, high-speed cutting and welding of metals and composition materials.

COHERENT TECHNOLOGIES, INC. 655 Aspen Ridge Drive Lafayette, CO 80026
Phone: PI: Topic#:	(303) 604-2000 Dr. AnnMarie L. Oien AF 01-006 Awarded: 02APR01
Title:	Tunable, Narrow Linewidth Laser for HF/DF Laser Metrology
Abstract:	Development of advanced Hydrogen Fluoride/Deuterium Fluoride (HF/DF) laser technology can be hampered by delayed knowledge of laser component performance. HF mirror optical performance metrology is currently costly and time consuming, requiring laser component delivery to an HF laser site, and operation of another HF laser to reach relevant wavelengths. Coherent Technologies, Inc (CTI) proposes a portable, turn-key solid state laser source providing over 1W narrow linewidth output, tunable to major HF laser lines (2.64 - 2.91 mm). A direct laser source is chosen instead of a nonlinear optical device because of the superior intensity stability and output power available - desirable in a metrology system. The proposed system could be transported to coating vendors for immediate diagnostic testing of mirror absorption and scattering at a range of HF laser lines. This will enhance the efficiency of the manufacturing process. Other possible applications include HF laser alignment and spatially resolved gain probing/imaging for decisive optimization of HF/DF laser performance. Phase I will consist of constructing a tunable, single-frequency laser, characterizing a HF/DF mirror sample, and designing a prototype brassboard HF mirror metrology system. The proposed work builds upon CTI's established background in tunable mid-IR laser sources and ruggedized single-frequency laser systems.A compact solid state tunable narrow linewidth source in the 2-3 mm wavelength region will accelerate HF/DF laser component metrology and alignment. Commercial applications include remote sensing, medical instrumentation, and as a pump source for mid-infrared nonlinear devices.

PHYSICAL SCIENCES, INC. 20 New England Business Center Andover, MA 01810
Phone: PI: Topic#:	(978) 689-0003 Dr. Steven J. Davis AF 01-006 Awarded: 04APR01
Title:	Advanced Diagnostics and Analytic Tools for HF/DF Laser Technology
Abstract:	Physical Sciences Inc. (PSI) proposes to develop two sensitive diagnostics for HF chemical laser development:. a) a novel patented, multispectral imager; Adaptive Infrared Imaging Spectroradiometer (AIRIS) and b) Planar Laser Induced Fluorescence (PLIF). In Phase I we will design, assemble, characterize, and field test an AIRIS device to demonstrate its capability to provide a sensitive diagnostic for the spatial and spectral content of HF lasers and profiles of HF(v,J) concentration and gain. We also propose to develop a design for a PLIF instrument that would be delivered in Phase II. This device would be used by HF researchers to design and test advanced mixing nozzles for future HF lasers. These two diagnostic tools would provide developers of high power chemical lasers with valuable data including spatial maps of populations of HF(v,J) levels, stability of HF output lines, and detailed maps of mixing. A successful Phase I and II program will result in two diagnostic devices that will be delivered to the Air Force. These tools will provide valuable design and verification data for development of the next generation of high power HF lasers. Follow on opportunities include diagnostics for ground based spaceborne lasers.

QEI TECHNOLOGIES, INC. 2715 S. St Paul Denver, CO 80210
Phone: PI: Topic#:	(303) 807-6051 Dr. John A. Bognar AF 01-007 Awarded: 18APR01
Title:	High-Performance Atmospheric Measurement System Using Kites and Blimps
Abstract:	The study of atmospheric turbulence and wind structure presents unique demands not currently met by commercially available atmospheric measurement systems. Remote sensors suffer from poor spatial resolution and often imprecise calibrations. In-situ sensors are either mounted on towers, which do not reach altitudes of interest, or on aircraft, which introduce a variety of artifacts into the data. Kites and blimps fill a niche between these existing platforms by providing a quiet platform from which to make measurements from the surface up to the free troposphere. The development of kites and blimps for atmospheric research requires the development of the profiling system itself and sensors suited to making measurements from these unique platforms. QEI Technologies proposes to develop a portable, user-friendly profiling system that will use a combination of high-performance kites and blimps to carry sensors through the boundary layer and into the free troposphere. An associated measurement package will be developed that provides three-dimensional wind data and interfaces to additional sensors. Phase I work will focus on the measurement package. Phase II work will see final refinement of the measurement package, the integration of this package with the profiling system, and extensive field tests of the combined system. The kite/blimp profiling system and associated wind measurement system will be useful to numerous government agencies and universities engaged in studies of fundamental wind and turbulence behavior, flux measurements, and transport and diffusion phenomena.

COHERENT TECHNOLOGIES, INC. 655 Aspen Ridge Drive Lafayette, CO 80026
Phone: PI: Topic#:	(303) 604-2000 Dr. Timothy Carrig AF 01-008 Awarded: 23MAR01
Title:	High-efficiency, frequency-agile MWIR-LWIR laser source for DIAL
Abstract:	The proliferation of chemical, biological and nuclear weapons among rogue nations and terrorist organizations necessitates that the US develop the means of detecting the development of these weapons before they can be deployed against US and allied military assets and civilian targets. The US government has demonstrated that Differential Absorption Lidar (DIAL) is one means of stand-off, covert, remote detection of chemical signatures characteristic of the development of these weapons. However, current DIAL transmitters lack the laser power and overall electrical efficiency needed for deployment onboard unmanned aerial vehicles or reconnaissance satellites. This program aims to demonstrate an innovative all solid-state laser transmitter suitable for incorporation into next-generation mobile DIAL sensors. A compact, high-efficiency, diode-pumped laser that pumps a single-stage optical parametric oscillator capable of simultaneous output in both the MWIR and LWIR spectral regions is proposed. The transmitter will be capable of electronically accessing any wavelength of interest and of scanning among wavelengths at a 10-50 kHz rate. In Phase I we will demonstrate that the proposed transmitter can meet DIAL wavelength, tuning and linewidth requirements. A detailed transmitter design will be developed. Additionally, risk reduction experiments will be conducted to demonstrate key elements of the design.Frequency-agile laser transmitters are needed for commercial DIAL sensors suitable for industrial chemical detection, pollution monitoring, and leak detection. These lasers are also useful for scientific applications such as high-resolution optical spectroscopy. High electrical efficiency infrared lasers are needed for variety of applications including wind-sensing, free-space optical communications, search and rescue beacons, infrared countermeasures and surgery.

Q PEAK, INC. 135 South Road Bedford, MA 01730
Phone: PI: Topic#:	(781) 275-9535 Dr. Yelena Isyanova AF 01-008 Awarded: 09APR01
Title:	Single-frequency, high-energy, tunable solid state IR source
Abstract:	Q-Peak, Inc. proposes to develop a single-mode, rapidly tunable, high-energy, high-average-power, all-solid-state IR source suitable for use as a direct-detection or heterodyne DIAL system transmitter. The source is based on the combination of a 1 micron pulsed pump laser and optical parametric oscillators (OPO). The pump source, designed as a oscillator-amplifier (MOPA) system, comprises a compact, diode-pumped, 500 Hz pulse-repetition-rate, single-frequency, Q-switched Nd:YLF laser and diode-pumped multipass Yb:S-FAP power amplifier. The MOPA system will pump a tandem OPO system consisting of a rapidly-angle-tuned, injection-seeded, 1.5-3.6 micron KTA OPO, and a pump-tuned, 3-5 micron and 8-12 micron CdSe OPO pumped by the KTA OPO idler. In the Phase I effort we will demonstrate an IR-source consisting of (1) an efficient, 500-kHz repetition rate, 1-micron source generating 15-mJ nsec pulses; (2) a tunable KTA OPO with a combined signal and idler average power of 2.5 W at 500 Hz repetition rate. Phase II development will emphasize technology that is ultimately field-suitable and efficient in terms of prime-power use, wavelength agility and single-mode operation.The proposed IR Laser Source will enhance selectivity and sensitivity of active, laser-based chemical effluent detection. In the commercial sector, the applications include wide-area pollution monitoring, process control, and general scientific investigations.

MISSION RESEARCH CORP. Post Office Drawer 719, 735 State Street Santa Barbara, CA 93102
Phone: PI: Topic#:	(937) 429-9261 Dr. Errol English AF 01-009 Awarded: 20APR01
Title:	Antenna Back-lobe and Side-lobe Suppression using Tapered Periodic Surfaces
Abstract:	Mission Research Corporation will design, fabricate, and test microwave antennas with very low side and back lobes using an innovative technology known as Tapered Periodic Surfaces (TPS). A TPS can be used as an edge treatment to drastically reduce EM field diffraction. A TPS is similar to a tapered R-Card, except that it is reactive rather than resistive. The TPS has many advantages over a tapered R-Card. These include; frequency compensation, ease of fabrication, polarization diversity, and high power robustness. In Phase I, several basic TPS structures (flat panels) will be designed, fabricated, and tested. These basic TPS designs will then be incorporated into a design of a simple demonstration antenna (TBD, but possibly a pyramidal or conical horn). Laboratory tests will be performed on this antenna to demonstrate the low side lobe effectiveness of the TPS treatment. Also in Phase I, a preliminary performance specification, as well as a conceptual design, will be generated for an advanced ultra-low side/back lobe antenna. This antenna will be designed, fabricated, and tested in Phase II.The satellite telecommunications industry is currently expanding at an incredible rate. With vast increases in the number of both satellites and ground terminals, interference between adjacent systems in a crowded envrionment is a serious problem. Ultra low side lobe antennas will be desperately needed. In parallel with this SBIR program, MRC will maintain a relationship with major non-military telecommunications companies in order to address their need for low side lobe antennas.

FARR RESEARCH, INC. 614 Paseo Del Mar NE Albuquerque, NM 87123
Phone: PI: Topic#:	(505) 293-3886 Dr. Everett G. Farr AF 01-010 Awarded: 20APR01
Title:	An Inflatable Membrane Impulse Radiating Antenna
Abstract:	Ultra-Wideband (UWB) antennas with broad bandwidth and large apertures could be of great use in a variety of space-based applications, including radar, communications, and surveillance. The challenge is to deploy a large lightweight UWB antenna that is stowable in a small volume, and that will be resistant to the harsh space environment. To overcome these challenges we propose an inflatable impulse radiating antenna fabricated from a thin membrane such as mylar or kapton. The proposed design is called a Membrane Impulse Radiating Antenna, or Membrane IRA. The antenna is inflated during deployment, and then the membrane may be hardened by epoxy or coated with a thin layer of foam that becomes rigid. In this manner, the antenna will be hardened against puncture by small space-borne particles. The Membrane IRA is a blend of two well-established foundation technologies. The first of these is the Collapsible Impulse Radiating Antenna (CIRA), which has an umbrella-like design and is now a commercial product. The second foundation technology is inflatable large-aperture reflectors fabricated from membranes such as mylar or kapton. The combination of these two technologies will lead to a space-capable deployable large-aperture antenna that is operational over two decades of bandwidth. During Phase I we will build and test a scale model of a Membrane IRA, with diameter of around four feet. Testing will include both a mechanical deployment demonstration and a measurement of the antenna pattern. We will also investigate methods of structurally hardening the membrane after deployment, so puncture becomes less of a problem. Finally, we will investigate replacing cables in the feed design with printed circuit transmission line.This research will lead to a new design for an inflatable Membrane Impulse Radiating Antenna. This device will have very broad bandwidth, will be lightweight, and will fit into a small volume on a satellite before deployment. A scale model approximately four feet in diameter will be built during Phase I.

LGARDE, INC. 15181 Woodlawn Avenue Tustin, CA 92780
Phone: PI: Topic#:	(714) 259-0771 Dr. Arthur L. Palisoc AF 01-010 Awarded: 27APR01
Title:	Space-Based Ultra-Wideband Antennas
Abstract:	Past efforts have demonstrated how inflatable parabolic reflectors could be made for space antennas. More recent laboratory studies have shown how a broadband antenna can result by coupling parabolic reflectors to specially designed impedance-matching support arms. We propose to combine the two technologies to create an inflatable space antenna made from the inflatable parabolic reflector and its inflatable support arms. Our goal is a lightweight broadband space-deployable antenna suitable as an impulse radar antenna or a general broadband antenna. Our approach is to draw on design options we have proven in past inflatable-structures programs for decoys, struts, antennas, and membrane supports. We will examine Conical Support and Tubular Support concepts for the arms/feed. Impedance of the various feed components will be matched to that of the antenna to minimize energy loss from the beam, using concepts proven on these past programs to vary the effective surface conductivity and geometry. An analytical model will be produced so that antenna design parameters can be varied and the resultant effects on gain and mass calculated. The best feed concept will be selected for bench tests to validate the model. Our team has unmatched experience in inflatable space structures and antenna design and test.We are developing, in conjunction with Applied EM, a complete antenna. It can therefore be offered as a subsystem to any mission that needs an IRA. However, the antenna is much more than an IRA. It is a broadband device and therefore capable of working at many different frequencies that might be of interest. Thus it is the first antenna that can be offered as a product applicable to most space projects. Therefore it offers the real possiblity of mass producing an inexpensive but effective space antenna.

G A TYLER ASSOC., INC. 1341 S. Sunkist St. Anaheim, CA 92806
Phone: PI: Topic#:	(714) 772-7668 Dr. Terry Brennan AF 01-011 Awarded: 16MAR01
Title:	Scintillation Resistant Wave-Front Sensors for Strong-Turbulence Adaptive Optics
Abstract:	Wavefront sensing in high scintillation environments is degraded in conventional sensors by a coupling, in the measurement, between phase and irradiance variations. An evaluation of this effect, and its impact on performance of systems, such as ABL, is proposed. An innovative wavefront sensor design has been proposed which mitigates this effect by pixel-level processing of the data. The design exhibits other advantageous features such as ease of implementation, elimination of the unobservable waffle mode, potential noise gain reduction, and measurements which permit both linear and non-linear (branch-cut) phase reconstruction. This design will be fully evaluated, analytically and in simulation, and fine-tuned as necessary. This proposed sensor design will improve phase gradient measurement precision in high scintillation, resulting in increased Strehl ratio performance of a conventional least-squares reconstruction. It will also support the use of branch-cut phase reconstruction.

AEROASTRO, INC. 520 Huntmar Park Drive Herndon, VA 20170
Phone: PI: Topic#:	(228) 466-9863 Mr. Paul Gloyer AF 01-012 Awarded: 26APR01
Title:	Lightweight Structural Aerobrake for Orbital Positioning and Maneuvering
Abstract:	The ability to maneuver, change orbits, and rapidly deploy spacecraft is a key requirement for the space user community. However, large and bulky propulsion systems with a significant mass of fuel on board often limit the maneuverability and capabilities of space vehicles. AeroAstro is developing aerobraking concepts and structures that use the Earth's atmosphere for braking and steering, significantly reducing the amount of propellant and even the type of propulsion systems required on spacecraft. Very lightweight aerobraking structures can enable significant reduction in mass coupled with an increase in capability. Using aerobraking, AeroAstro is developing with commercial funding the Small Payload ORbit Transfer (SPORTT) system to enable small payloads to use low-cost secondary launch opportunities and still reach custom orbits. A lightweight aerobrake structural design is key to the SPORT concept. To fit within constrained volumes, aerobraking structural members must be tightly packaged and lightweight. Structural booms must deploy to approximately ten times their length to produce a seventy-fold increase in profile area. AeroAstro proposes to investigate various applications and structural technologies for the aerobrake design. TThe use of aerobraking provides spacecraft and vehicles like SPORT with a much greater orbit transfer capability than that achievable with direct propulsion. Aerobraking reduces the ?V requirement for a GTO to LEO orbit transfer from a costly 2,340 m/s down to an affordable 378 m/s, an amazing 84% reduction in ?V requirement. While the GTO to LEO case is extreme, other transfer missions, such as GEO to LEO and LEO to Intercept, each reveal a 50% savings in the ?V requirement. This will result in a massive reduction in launch costs for small satellites. The aerobraking technology payoff is significant, with commercial and government utility forseen not only for the SPORT vehicle, but also in a variety of other applications. Potential applications for the aerobraking technology include population of microsatellite constellations, situational pre-positioning, and space asset resupply. There are numerous potential customers, both government and commercial, for the technology that AeroAstro is proposing to develop. The first customer for this aerobraking technology will likely be a customer for AeroAstro's SPORT vehicle. A commercial customer is already funding a feasibility study for the first SPORT, which could be launched in 2003-2004.

MODULAR DEVICES, INC. 1 Roned Road Shirley, NY 11967
Phone: PI: Topic#:	(631) 345-3100 Mr. Mark B. Graham AF 01-014 Awarded: 24APR01
Title:	Lightweight DC/DC Power System
Abstract:	This opportunity relates to the ability to construct a flexible power system that is capable of operating from one power source or power multiple sources. The system would be composed of multiple lower power DC-DC converter units, which can be paralleled to expand power outputs in discrete multiples, sharing power loads relatively uniformly. This flexible power system would be comprised of small modules, each handling a small fraction of the overall power.The availability of a flexible power converter architecture could allow faster power bus development and allow stocking of a small number of common part types for multiple applications. This can result in large cost savings due to amortization of space related lot costs such as element qualification and radiation tests.

NVE CORP.(FORMERLY NONVOLATILE ELECTRON) 11409 Valley View Road Eden Prairie, MN 55344
Phone: PI: Topic#:	(952) 996-1610 Mr. John K. Myers AF 01-015 Awarded: 23APR01
Title:	High Speed Digital Bus Isolator for Space Applications
Abstract:	NVE will produce and package IC's that monolithically integrate their existing high speed GMR signal isolator silicon into a prototype 800 Mbits/sec. 8 bit transceiver. Commercial high speed data bus interfaces between subsystems such as IEEE 1284 and IEEE 1194 have not been galvanically isolated due to performance, size and cost constraints. These interfaces would benefit from the inclusion of monolithically integrated high performance galvanic isolation barriers. The proposed device will eliminate noise, cross talk, and ground bounce and allow highly parallel long distance bus architectures. Products will find wide application in aerospace, military and commercial applications which require both high speed transceiver circuitry and galvanic signal isolation. NVE has successfully integrated IsoLoopr galvanic monolithic isolation technology into single and dual channel transceiver silicon and will use this foundation to design/build isolated 8 channel 74245 type transceiver circuits and design 8 channel 74574 type latch solutions. This technology simultaneously meets requirements for high speed, low power, noise immunity and design flexibility required for high performance data busses. The Phase II program develops 3.3 volt radiation tolerant 4 or 8 channel die for production worthy 8 bit latch/transceiver designs. Products decrease component footprint, weight and power for other systems.This project will prove the feasibility of large scale implementation of NVE's Isoloop technology for use in computer bus interface applications. External interfaces to computers often must interface through a multi-channel parallel bus structure that today cannot be practically isolated. These non isolated bus interfaces often cause internal damage to computer systems due to grounding problems. This specific commercial market potential is estimated to exceed $50M. If the project is successful, it could lead to a product that can solve this technological problem and expand and create new markets.

INTEGRATED MAGNETOELECTRONICS 1214 Oxford St. Berkeley, CA 94709
Phone: PI: Topic#:	(510) 841-3585 Mr. Richard Spitzer, Ph.D AF 01-016 Awarded: 23APR01
Title:	Field Programmable System-On-A-Chip
Abstract:	The proposer (IME) is developing general-purpose electronics based on giant magnetoresistance (GMR). Underlying IME's all-metal electronics is the transpinnor, a novel device that allows amplification and either logic or linear characteristics. IME has designed and fabricated several transpinnor-based logic gates and simple linear circuits; intial tests have been completed, and a second development cycle is in progress. The phase I project objective is to demonstrate the feasability of an all-metal field programmable SOC. Transpinnors will be used for nonvolatile switches, logic gates, and an FPGA. The functional elements of the FPSOC will be designed, modeled and simulated, as will the FPSOC as a whole. The transpinnor will be made of the same materials as IME's nonvolatile GMR RAM. A successful project will provide the foundation for a variety of all-metal reconfigurable Systems-On-A-Chip.A specific FPSOC will provide a nonvolatile radiation-hardened switching system for routing telecommunications signals over a wide variety of networks, e.g., internet, phone lines, communications satellites, etc.. The individual elements will provide building blocks for other FPSOC's.

MISSION RESEARCH CORP. 735 State Street Santa Barbara, CA 93101
Phone: PI: Topic#:	(505) 768-7641 Mr. Robert M. Turfler AF 01-017 Awarded: 13APR01
Title:	A Monolithic Advanced Instrument Controller Employing Mixed Technology System-On-A-Chip
Abstract:	Mission Research Corporation (MRC) proposes to design and develop a mixed signal system-on-a-chip based on the Advanced Instrument Controller (AIC) multi-chip module, previously developed by MRC. Specifically, we will design a monolithic, radiation hardened version of the AIC for the Peregrine fully depleted CMOS/SOS process. As a minimum, the monolithic AIC will include an 8031 equivalent microcontroller, a digital port expander, a memory controller with EDAC (error detection and correction), a 12 bit analog to digital converter, a 32-to-1 analog multiplexer, a voltage reference, and eight, 10 bit digital to analog converters. Depending on the results of our proposed Phase 1 investigation, it may also include on-chip RAM, ROM, and EEPROM.A radiation hardened, monolithic Advanced Instrument Controller will significantly reduce the size, weight, and power as well as cost for point of use microcontrollers in space and missile systems. It will also have applications in the commercial sectors for autonomous controllers of sensors and other instruments.

PHOTOBIT CORP. 135 N. Los Robles Ave., 7th Fl Pasadena, CA 91101
Phone: PI: Topic#:	(626)6832200 Dr. Eric Fossum AF 01-018 Awarded: 23APR01
Title:	Radiation Tolerant System-On-A-Chip for Space
Abstract:	The purpose of this work is to identify/resolve deterrent factors to implement radiation tolerant image sensor system-on-a-chip (SOC). Thisis done by integrating radiation tolerant image sensor blocks on space system-on-a-chip (SOC) ICs that is expected to total dose up to 1Mrad(Si). Photobit has recently completed an SBIR project that concluded that radiation hard CMOS APS image sensors are feasible. The combination of employing the physical design techniques of enclosed geometry and guard rings, and a deep sub-micron standard CMOS fabrication process provides the path to radiation hard CMOS APS image sensors SOC IC's. Along the way, it is necessary to develop and prove other system level blocks operating as an integral part of an imager SOC such as digital control blocks, data storage and communication blocks, etc.. In Phase I of this SBIR project, these blocks will be developed, simulated, and integrated with already developed CMOS APS image sensor blocks to construct radiation hard CMOS APS image sensor system-on-a-chip (SOC) for space applications. Final design will be made ready for submission for fabrication.Radiation hard CMOS APS image sensor system-on-a-chip (SOC) ICs will pave the way for low cost, radiation hard, low-power, miniature camera solutions for space and earth based applications. CMOS APS image sensors perform as well as CCDs, with the added benefits of lower power (10 to 100 times less) and integration of electronics (enabling miniaturization and SOC solutions). This allows them to not only compete in the same markets as CCDs, but also provide opportunities to expand the existing image sensor market. The proposed radiation hard image sensor and the technical advances associated with its development are extremely important for space applications (DoD, NASA, and commercial satellites) and ground-based based radiation harsh environment systems such as nuclear power plants, particle accelerators, and radiation test facilities.

ADVANCED SOLUTIONS, INC. 6901 S. Pierce St, Suite 301 Littleton, CO 80128
Phone: PI: Topic#:	(720) 218-7584 Mr. Allen W. Bucher AF 01-019 Awarded: 28MAR01
Title:	Low-Cost/Robust Nanosatellite Spacecraft for Distributed, Communication Systems Constellations
Abstract:	Both DOD and NASA have future missions that require the launch and deployment of an increasing number of single spacecraft, as well as multi-craft constellations. The desire to minimize cost and ensure the robustness of these high value assets has given rise to the need for on-orbit inter-satellite communications that provides redundancy and fault tolerant satellite-to-satellite communications. The increased use of the Internet and wireless technologies for terrestrial based communications has sparked advancements in the robustness and reliability of hardware and software components. Using these methodologies, ASI is proposing a Satellite Constellation Internet Protocol (SCIP) for Satellite Constellation Management. ASI will develop methodologies that will allow the expansion of the current internet to space based hosts. These hosts will have the capability to communicate, exchange information, and route traffic to other nodes as if they were terrestrial based. The SCIP will leverage current internet technologies and enhance them to handle the space environment and increased node-to-node latency.Robust Satellite to Satellite communications. High Bandwidth communications to areas without high bandwidth infrastructure. Satellite constellation management methodologies. Low cost, low risk, high fault tolerant communications networks in the sky.

ALAMEDA APPLIED SCIENCES CORP. 2235 Polvorosa Ave, Suite 230 San Leandro, CA 94577
Phone: PI: Topic#:	(510) 483-4156 Dr. Niansheng Qi AF 01-019 Awarded: 06APR01
Title:	Vacuum Arc Nano Thrusters for Nanosatellite Spacecraft Constellations
Abstract:	Alameda Applied Sciences Corporation proposes to develop a new type of nano-thruster electric engine for highly parallel, distributed constellations of nano-satellites and other space propulsion applications. A key feature of the proposed Phase-I is the use of an Inductive Energy Store (IES) driver to power the vacuum arc nano-thruster, which has a mass of <60 g while operating at >90% PPU efficiency from 1-10 W. The province of missions for such a thruster includes attitude control of satellite constellations of Class I microspacecraft (~10 kg, ~10 W). This thruster requires <100 V to operate, vs. the ~2 kV for the PPT. The thruster might be scaled to >=100 W, to provide both attitude control and slew maneuvers with the same engine. In Phase I, AASC will fabricate a prototype thruster with a 1-10 W inductive PPU, using NASA and/or Air Force space qualified components where possible. We will measure plasma streaming velocity and mass utilization rates for many elements or alloys. We will conduct direct thrust and efficiency measurements at Edwards AFB. In Phase II, we will develop a flight qualified engineering model by addressing other key issues such as the lifetime of the thruster, environmental factors and mission requirements.The primary application of the specific thruster to be developed in the proposed work will be for Class I micro-spacecraft, ~10 kg. However, beyond this immediate application, the thruster could find use for larger or smaller spacecraft, with further development.

ONTARIO ENGINEERING INTERNATIONAL 3333 Harrision Street, Unit #6 Riverside, CA 92503
Phone: PI: Topic#:	(909) 283-5971 Mr. Russell Abbott AF 01-020 Awarded: 20APR01
Title:	Opto-Interconnection System
Abstract:	A fiber optic device connector will enable the development of a new generation in optical computer technology. By developing an optical interconnect that connects to the transmit and detector elements mounted in the device will improve system performance through increased data transmission rates, lower power consumption, opto-isolation of all I/O and a enabling of the single point ground philosophy. Current fiber optic systems use discrete devices to covert the light pulses from the fiber optic cable into electrical signals. These signals are then conducted to the next device using a printed wiring board to high-count I/O packages. These signals are then demultiplexed down to a lower data rate required by the lower speed, low power technologies. As a consequence the I/O increases to maintain the data rate. I/O power is a significant contributor to the overall power consumption of the IC. By integrating the transmitter, detector and fiber optic cable connection into the device package the device I/O pin count can be reduced. This allows a significant reduction in the device power requirements that are needed to drive the I/O and an increase in the data transfer rates by not having to leave the device package.These efforts will offer major savings on device power consumption, inherent radiation hardness, increased reliability through elimination of solder joints, increased immunity from electrical noise and crosstalk.

MISSION RESEARCH CORP. 735 State Street Santa Barbara, CA 93101
Phone: PI: Topic#:	(505) 768-7788 Mr. Daniel King AF 01-021 Awarded: 13APR01
Title:	Enhanced Hardened By Design (HBD) EDA Environment
Abstract:	Mission Research Corporation (MRC) is proposing the enhancement of the Hardened by Design concepts and MRC Libraries to address emerging radiation issues for Single Event Transient, Neutron Induced Upsets, and Dose Rate Hardness through a hierarchical design process. The existing libraries already incorporate design techniques to address Total Ionizing Dose, Single Event Latchup, and Single Event Upsets. Further, MRC proposes the integration of the MRC Hardened by Design, deep submicron cell libraries into the Synopsys (TM) design environment. The approach will address foundry independent fabrication techniques for radiation hardened electronics. Specifically, we will enhance the scalable 0.35 and 0.25 micron, hardened by design (HBD) cell library to support the radiation hardening of ASICs fabricated in commercial silicon foundries, but exhibiting total dose hardness in excess of 300 Krad(Si), single event effects immunity, and dose rate hardness in excess of 1x10^9 rad(Si)/s. The improved performance and radiation hardness will be demonstrated by using Synopsys DesignWare (TM) components.Radiation hardening techniques for foundry independent fabrication design flow for radiation hardened electronics in support of system on a chip development. The enhanced HBD libraries and design flow will enable higher performance, lower power, and lower size and weight designs for space and strategic applications. The approach will lead to more cost effective electronics designs. MRC's proven design experience and expertise will lead toward new capabilities for the space electronics design.

VIBRO-ACOUSTIC SCIENCES, INC. 12555 High Bluff Drive, Suite 310 San Diego, CA 92130
Phone: PI: Topic#:	(858) 350-0057 Dr. Bryce Gardner AF 01-022 Awarded: 27MAY01
Title:	Advanced Composite Acoustic Blanket Development
Abstract:	In Ph.I Vibro-Acoustic Sciences will extend and apply its acoustic modeling technology to investigate an entirely new class of blanket construction - "heterogeneous construction" - as a means to achieve better low- and mid-frequency attenuation of acoustic levels in launch vehicle fairings. Candidate heterogeneous blanket concepts include Prof. C.R.Fuller's distibuted vibration absorber and NAMRL's embedded particle matrix materials. Acoustic tests will be used to validate a Blanket Design Procedure. A best "noise reduction per unit weight" blanket design will be undertaken for a selected launch vehicle fairing. The blanket will be fabricated and ground tested in an acoustics lab to prove its feasibility for full scale fairing application and evaluation in Phase II.Improving the acoustic environment in launch vehicle fairings will allow the use of more low cost COTS equipment on Air Force space flight projects and will reduce the test requirements for new flight hardware. There are also significant opportunities to apply this technology to new noise control solutions for transport vehicles, including the $20 billion automobile interiors market.

CFD RESEARCH CORP. 215 Wynn Dr., 5th Floor Huntsville, AL 35805
Phone: PI: Topic#:	(256) 726-4800 Dr. Marek Turowski AF 01-023 Awarded: 23APR01
Title:	New Design Technologies for Radiation Hardened Microelectronics
Abstract:	Radiation-hardening by design (RHBD) allows to use available commercial fabrication lines of high performance circuits, but the radiation-hardened (rad-hard) devices and cells require larger area, higher-power consumption, and slower performance. CFDRC in collaboration with Mission Research (David Alexander) and Vanderbilt University (Ronald Schrimpf) is proposing to develop novel, radiation-hardened by design concepts, at the transistor and primitive cell level, that are spatially compact in comparison to currently used rad-hard designs. The new, innovative rad-hard circuit design technology will include: 1) An integrated computational environment to provide quantitative assistance in developing new rad-hard designs, utilizing 3D device simulations with advanced semiconductor models enhanced with radiation effects; 2) Numerical, automated optimization of primitive logic and memory cell designs (layouts) for mitigation of Single Event Effects in modern submicron CMOS technologies, including SOI; 3) Calculation of key operational parameters of the designed cells, to indicate that the designs will tolerate radiation exposure to specified levels. Special attention will be given to single event latchup (SEL) vulnerability. In Phase II, the RHBD software will be enhanced with TID phenomena, and the optimized designs of primitive logic and memory cells will be fabricated and electrically characterized to demonstrate their radiation-hardness to TID, SEL, and SEU.All federal and commercial organizations that are involved in putting vehicles into space would benefit greatly by having access to high-performance, radiation-hardened microelectronics that are readily and cost-effectively produced. DoD also has many non-space applications for radiation-hardened microelectronics.

JAYCOR, INC. 3394 Carmel Mountain Road San Diego, CA 92121
Phone: PI: Topic#:	(256) 837-9100 Mr. T. G. Bo Henderson AF 01-024 Awarded: 23APR01
Title:	Direct Thermal to Electric Energy Converter
Abstract:	A great and pervasive need exists for new, innovative concepts for the generation of electric power in earth orbit. All US spacecraft rely on solar cells for their primary power source. The most advanced solar cells under development are at most 40% efficient. A novel technique with higher efficiency is needed to enhance mission capabilities. That novel concept is thermionic emission from microtip arrays. It is anticipated that efficiencies as high as 60% are achievable with current densities greater than 10 amps per square centimeter. This program will further develop and refine the geometry, and band/field structure of diamond microtip arrays to maximize durability, efficiency, and capacity. The goal of this program is to develop compact efficient energy conversion devices for space and ground based applications. The Phase I program will demonstrate the feasibility of this technology by a combination of lab measurements and analysis.In addition to providing an efficient power source for government and commercial satellites, efficient direct thermoelectric conversion will support many electrical generation systems including nuclear and fossil fuel power plants. The increased efficiency will allow the more economical use of renewable energy sources such as solar and geothermal. The broad temperature operating range of this technology will support many applications.

SYSTRAN FEDERAL CORP. 4027 Colonel Glenn Highway, Suite 210 Dayton, OH 45431
Phone: PI: Topic#:	(937) 429-9008 Mr. Todd Grimes AF 01-025 Awarded: 23APR01
Title:	Improved Analog-to-Digital Converter Fabrication Techniques
Abstract:	An innovative ADC architecture known as Parallel Time Interleaved Multi-bit Feedback (PTIMF) has been invented by Prof. Ray Siferd of Wright State University and Systran Federal Corp. The PTIMF architecture offers several advantages over existing parallel Delta-Sigma ADC architectures, such as, Reduced oversampling ratios (OSR), Less hardware intensive implementation, Reduced filtering requirements, etc. In addition, the PTIMF architecture facilitates the design of ADCs with the following attributes: High Speed, High Resolution, Increased Bandwidth, and Reduced power consumption. The most beneficial feature of the PTIMF architecture is scalability and its applicability to any fabrication process. The number of channels and/or the OSR may be scaled to facilitate the required resolution (12-bit, 16-bit, 18-bit, 20-bit, 24-bit, etc.) and the bandwidth. Dr. Cerny of SN/AFRL and his colleagues have invented a new, patented process from known as "Xs-MET". Devices built using the Xs-MET process are inherently radiation hardened at > 500 Kilorads. This proposal will apply the PTIMF architecture to potentially rad-hard processes (e.g., Xs-MET) and develop ADCs for space applications. In addition, we also plan to investigate the possibility of adding "circuit elements" to the PTIMF architecture that will make the components rad-hard. ADCs designed in this SBIR program will not only have high-performance characteristics, but will also be rad-hard. Hence, they will be extremely useful for space-based applications.

AET, INC. 1900 S. Harbor City Blvd., Suite 115 Melbourne, FL 32901
Phone: PI: Topic#:	(321) 727-0328 Dr. Glenn T. Hess AF 01-026 Awarded: 23APR01
Title:	Single Event Transient Soft Error Rate Prediction in Integrated Circuits
Abstract:	Single event transient (SET) effects on combinational logic have not been widely studied because they have been deemed less important than logic circuits until the advent of deep sub-micron technologies. These new circuits tend to be more sensitive to SET because of the higher operating speeds and higher clock rates, and the smaller transistors themselves are more sensitive to radiation. AET, Inc. is developing a methodology to analyze the SET induced soft error rate in logic circuits. The approach is to model these SET induced soft error rates as functions of the design and technology of the integrated circuit. The models will be incorporated into a software tool that will be utilized by development engineers. This tool will be complimentary to an AET tool presently in development aimed at calculating critical charge and total dose effects in integrated circuits. As a proof of concept, AET will design test structures to verify the validity of the approach and the AET software tool. Based on the results of this work, AET will predict the primary factors contributing to SET susceptibility of the test structures. Using the AET statistical analysis methodology, AET will develop a preliminary SET mitigation strategy. The primary benefit of the SET software tool will be to US Air Force advanced space systems and commercial companies that supply IC's to these systems. Commercial satellite programs as well as military systems will utilize this technology to improve system performance and lower costs.

MATERIALS & SYSTEMS RESEARCH, INC. 5395 West 700 South Salt Lake City, UT 84104
Phone: PI: Topic#:	(801) 530-4987 Dr. Tad J. Armstrong AF 01-027 Awarded: 07APR01
Title:	Fabrication of Highly Conductive, BASE-Header Assemblies by a Novel Process, and Evaluation in AMTEC
Abstract:	This proposal by Materials and Systems Research, Inc. (MSRI) is on the fabrication of Na-beta"-alumina-containing solid electrolytes (BASE) by a novel, patented process, and evaluation of performance in an AMTEC. The process converts sintered alpha-alumina containing bodies directly into BASE. The resulting BASE is resistant to attack by moisture, unlike BASE made by a conventional process. The process is also amenable to integration of an insulating header, required for attachment to other cell components, without the necessity of using a sealing glass. The proposed approach should result in highly conductive, mechanically strong, water-resistant BASE. Minimization of the number of steps in processing, and minimization of number of components is expected to lead to significant cost savings. Higher conductance compared to BASE made by conventional processes also should lead to higher performance. In Phase I, MSRI will fabricate and characterize BASE-header assemblies, and evaluate their performance in an AMTEC.The proposed approach for the fabrication of BASE offers the following benefits over the state-of-the-art methods. The proposed method: (a) Does not require encapsulation for sintering. (b) Higher mechanical strength. (c) Is resistant to attack by moisture. (d) A glass-free alpha-Al2O3-BASE header. (e) Low cost. Potential commercial benefits include applications in AMTEC, sodium-sulfur batteries, and sensors. AMTEC has applications in satellite power, uninterrupted power supplies (UPS), and residential power. Sodium-sulfur batteries have applications in distributed power, load-leveling in the utility industry, and for transportation.

ARCHITECTURE TECHNOLOGY CORP. 9971 Valley View Road Eden Prairie, MN 55344
Phone: PI: Topic#:	(952) 829-5864 Jordan C. Bonney AF 01-028 Awarded: 06APR01
Title:	Ad Hoc Routing for Nanosatellite Constellation Communications
Abstract:	This proposal suggests an approach to providing self-organizing network communications between the nodes comprising a nanosatellite constellation. Using the proposing firm's existing body of work on self-organizing ad hoc networks for 802.11 wireless LANs and miniaturized robotics platforms as a baseline, issues relating to ad hoc networking in a nanosatellite constellations will be identified, a candidate communication architecture will be developed, and OPNET models of a modified ad hoc routing protocol will be developed. The simulation results will be used to assess the feasibility of the approach. By applying the lessons learned from terrestrial ad hoc networks to a spaceborne environment, and by using existing routing algorithms as a baseline, a flexible communications infrastructure that enables the deployment of cooperative software on the various nodes of a nanosatellite constellation can be developed in a relatively short period of time. The commercial application of this research is a routing algorithm that can be licensed to nanosatellite communication-hardware vendors.

NVE CORP.(FORMERLY NONVOLATILE ELECTRON) 11409 Valley View Road Eden Prairie, MN 55344
Phone: PI: Topic#:	(952) 918-1151 Dr. Zhenghong Qian AF 01-029 Awarded: 23APR01
Title:	High Speed Linear Spin-Valve Sensors for Analog Isolator Applications
Abstract:	This Small Business Innovation Research Phase I project will demonstrate two types of linear spin-valve sensors with excellent linearity and sensitivity as well as optimized bias points, and will also demonstrate the feasibility of their application in analog isolator devices. The first type of linear spin-valve sensor will be designed similarly to a spin-valve recording head. The second type of linear spin-valve sensor will be designed and fabricated using a novel approach with a free ferromagnetic (FM) layer exchange-biased with an antiferromagnetic (AF) layer. The sensor performance will be optimized by materials selection and process control as well as magnetic design. The ultimate goal in this program is to fabricate and demonstrate analog isolator devices using linear spin-valve sensors developed in Phase I. The current NVE digital isolator process will be modified into an analog isolator process for this purpose. The success of this Phase I project will provide a solid framework for the Phase II to build high speed, linear radiation-hard analog isolator devices.The linear spin-valve sensors developed in this research has immediate application in NVE's isolator technology, which will lead to the addition of the analog isolator devices into its isolator product catalog. In addition, the linear spin-valve materials can also be used in field sensors and read head devices.

MICROCIRC ASSOC. 102 Scholtz Plaza, No.238 Newport Beach, CA 92663
Phone: PI: Topic#:	(949) 548-5214 Dr. T.P. Haraszti AF 01-030 Awarded: 25APR01
Title:	Radiation-Hardened Synchronous SRAM
Abstract:	Novel radiation-hardened synchronous pipelined multibank fault-tolerant static-random- access-memory (SRAM) will be developed. The SRAM will combine high speed performance and radiation-hardness with high packing density, low power consumption and manufacturability at reasonable costs. Unique circuits and circuit organization, i.e. self- compensating current-sense, voltage limiters, parameter-tracking references, self-adjusting logic, shuffle, error corrector and fault-masking circuits, will contribute to narrow or close the speed-gap between radiation hardened SRAMs and the digital-signal-processors DSPs. Fault- tolerance will be used only to the level that satisfies the requirements. In Phase I, the architecture and the key circuits and a test-chip concept will be developed, in Phase II a complete SRAM will be designed, fabricated and evaluated, and in Phase III modified SRAM designs will be commercialized. The outcome of this effort will be key elements in future defense systems, commercial satellites, cosmic missions, nuclear weapons, power sources, propulsion devices and in other radiation hardened ambiences.The anticipated results of this research and development program can lead to a breakthrough in the implementation of an advanced national defense-system. Namely, the proposed SRAM is a key element that can satisfy the elevated requirements in operational speed and radiation hardness. The private industry would progress in obtaining high-reliability fast SRAMs for applications in extreme environments.

MIDE TECHNOLOGY CORP. 56 Rogers Street Cambridge, MA 02142
Phone: PI: Topic#:	(617) 252-0660 Dr. Leo Casey AF 01-031 Awarded: 02APR01
Title:	Smart Adaptive Power Converter
Abstract:	Mide is proposing to investigate the use of adaptive control algorithms to enhance total system performance of switching power amplifiers and converters, with intended implementation in a radiation hard dc-dc converter. Mide is also proposing to investigate the area of component adaptation in these systems, with the focus on the use of variable power reactances, and adaptive rectifiers (variable V-I characteristic for semiconductor switching devices). The innovative concepts include: 1) digital implementation of feedback and feed-forward power controllers for high frequency switching amplifiers, permitting load dependent tuning of controller operation 2) extension of synchronous rectifier concepts to allow power MOSFETs to achieve wider range of terminal characteristics to assist in converter adaptation 3) investigation of variable power reactances for converter adaptation. In Phase II Mid� will develop/design and "qualification" test a prototype adaptive power converter to demonstrate the technology and to ease its transition to application by commercial and military spacecraft. Current economic pressures arising from higher fuel prices are an important reason why this technology is timely and important. A significant number of commercial converters are driving variable reactances and improved efficiency will directly translate into fuel/energy savings. The primary application will be converters for the telecommunications industry. The non-captive high-density power converter market is approximately $10B.

BUSEK CO., INC. 11 Tech Circle Natick, MA 01760
Phone: PI: Topic#:	(508) 655-5565 Dr. V. Hruby AF 01-032 Awarded: 12APR01
Title:	Field Emission Cooler Development
Abstract:	The on-going miniaturization of satellites requires concurrent development of miniaturized cooling/heat rejection devices. Cooling by field emission of electrons offers an attractive approach that until recently could not be considered. To test it, we have conducted preliminary experiments and measured significant emitter cooling/temperture drop using an unoptimized carbon nanotube (CNT) field emission (FE) cathode originally constructed for low power electric propulsion applications. Approximate analytical model was developed to explain the observed behavior. The model indicates that heat transport approaching a mW was accomplished and that a theoretical limit is of the order of 100 W/cm^2. Thus cooling by electron field emission is feasible and its development is herein proposed. In Phase I we will construct an improved FE device for the purpose of accurate calorimetric measurement of heat rejection from the emitter/cathode and heat gain on the anode. Emission experiments will be conducted in temperature range from 400 to 77 K to determine the feasibility of cryogenic FE coolers. The experiments will be supported by concurrent modeling to develop performance prediction capability. A search for early FE cooler application will be conducted and the identified application will be the focus of the Phase II device development. Cost effective, high efficiency, compact FE coolers would find application in many space and terrestrial devices in both military and commercial markets. These devices include IR sensors and imagers, cryogenic storage, magnetic resonance imaging and refrigeration in medical applications, high density digital processors and power electronic components. The market is in the $M annually.

STAR CRYOCOOLERS, LLC 505 Oppenheimer Dr. Suite #804 Los Alamos, NM 87544
Phone: PI: Topic#:	(505) 662-1585 Dr. Bradley C. Edwards AF 01-032 Selected for Award
Title:	The Solid-State Optical Cryocooler
Abstract:	Cryogenic systems are becoming more important to the Air Force and commercial interests. Such systems are utilized both in space and on the ground. An ever growing number of applications require cooling; from high performance sensor systems to superconducting electronics. However, cryogenic systems often create as many problems as they solve. When mechanical cryocoolers are used vibrations, power consumption, survivability and complexity become real issues. When cryogens are used maintenance, complexity and lifetime become issues. In our proposed Phase I effort we will study an emerging technology, optical cryocoolers, that will provide a revolutionary way to achieve cryogenic temperatures. The optical cryocooler is a solid state device that offers a number of distinct advantages over its mechanical counterparts. It is non-mechanical, vibration-free, temperature selectable, scalable to small size, rugged, likely to be long-lived, reliable, and lightweight. Given this technical promise, it may uniquely address future Air Force and commercial needs. The proposed research to develop an optical cryocooler would reduce or eliminate many of the problems currently experienced in cryogenic applications. With its unique characteristics the optical crycooler would be ideal for use in Air Force and DoD space and ground-based applications as well cooling commercial computer chips and high-temperature superconducting systems. These markets range from tens of millions of dollars per year for specific space applications to possibly over a billion dollars per year in future telecommunications applications.

IOWA THIN FILM TECHNOLOGIES, INC. 2337 230th St Boone, IA 50036
Phone: PI: Topic#:	(515) 292-7606 Frank Jeffrey AF 01-033 Awarded: 27MAR01
Title:	High-Efficiency Amorphous Solar Cells on Polyimide Web
Abstract:	Thin film photovoltaic modules fabricated on polymer substrates have a number of very attractive features for space use. Flexible a-Si modules: 1) have shown minimum degradation due to radiation; 2) can have low fabrication costs; 3) have demonstrated very high power to weight ratios; 4) have high tolerance to vibration and shock; 5) can be monolithically integrated to give very flexible design options. Iowa Thin Film presently manufactures ultra lightweight amorphous silicon solar cells using a polyimide web substrate for the terrestrial market. Typical efficiency for the terrestrial product is approximately 5%. Finished solar cells of this type are presently capable of a specific power of 750 W/Kg. With a full focus on developing maximum efficiency for space use, laboratory results indicate that efficiency could approach 10% Under this effort, ITFT proposes a systematic program to transition our existing production-based terrestrial flexible monolithic integrated a-Si to a low cost space-rated PV. Since ITFT has already developed the core manufacturing processes of depositing on a flexible polymeric substrate and monolithic integration, we are in the unique position of being able to concentrate solely on the issues associated with converting a low-cost terrestrial PV into a space PV. The primary goal of Phase I is to develop and demonstrate the feasibility of a new deposition process for a back surface reflection enhancing layer on our roll to roll fabricated, polymer based devices.In addition to lightweight power for space use, polymer based flexible photovoltaics have significant other DOD uses. These include lightweight portable fold-up or roll-up modules for field communications and modules integrated into tents or other temporary structures to power communications, lighting and filtering systems. Commercial uses include photovoltaics integrated into building structures for grid and non grid power as well as power for portable electronic devices. Power integrated into emergency shelters is another use.

NANOSONIC, INC. P.O. Box 618 Christiansburg, VA 24068
Phone: PI: Topic#:	(540) 953-1785 Dr. Kristie Cooper AF 01-033 Awarded: 27APR01
Title:	Ink Jet Print Self-Assembly of Polymer Thin Film Solar Cells on Polyimide Substrates
Abstract:	This Air Force Phase I SBIR program would demonstrate the feasibility of ink jet print electrostatic self-assembly (ESA) processes for the low-cost fabrication of flexible photovoltaic arrays directly on polyimide substrates. ESA processing involves the coating of substrate materials by the alternate adsorption of anionic and cationic complexes of polymers, metallic nanoclusters and other molecules from water-based solutions at room temperature and pressure. By controlling the molecules deposited in each monolayer of the resulting multilayer thin film, optoelectronic devices with high efficiency may be formed. Specifically, photon-to-electron conversion with high quantum efficiency can be achieved in layer-by-layer polymer dye/nanocrystalline semiconductor films, due to the high effective inter-particle surface contact area at the molecular level, and by using metal nanocluster/poly-dye multilayers to enhance optical absorbance. NanoSonic's recent work in this area, in cooperation with a large U.S. aerospace contractor, has demonstrated such high quantum efficiencies in ESA-fabricated devices, and the ability to form such functional thin films as coatings on mechanically flexible substrates. During Phase I, NanoSonic would work with that company to demonstrate the ability to reproducibly form deployable photovoltaic arrays on polyimide substrate materials, and investigate methods to improve quantum efficiency, fabricate electrode interconnections and implement effective device packaging.Photovoltaic arrays that may be integrated directly with space qualified materials offer unique opportunities for electrical power generation for both military and commercial applications. Easily-deployed power generating materials would reduce the need for batteries and for separate mechanically rigid solar cell arrays in space-based and terrestrial portable and mobile platforms. Low-cost processing methods such as ink jet print self-assembly at room temperature would allow cost-effective power generation.

NVE CORP.(FORMERLY NONVOLATILE ELECTRON) 11409 Valley View Road Eden Prairie, MN 55344
Phone: PI: Topic#:	(952) 996-1616 Mr. Robert A. Sinclair AF 01-034 Awarded: 23APR01
Title:	Radiation-Hardened Non-Volatile RAM
Abstract:	Nonvolatile memories, including Magneto Resistive Random Access Memory (MRAM), have limitations in speed, density, power, and manufacturability which limits their use in commercial and space applications. A unique nonvolatile memory architecture has been invented by NVE using a patent pending Spin Dependent Tunneling (SDT) cell that will eliminate these limitations. The newly invented SDT nonvolatile memory technology, of which NVE is among the leading researchers, allows a high density and also the lowest energy per bit write or read of any nonvolatile memory technology. Magnetic memory has been demonstrated to be immune to radiation effects and is compatible with silicon-On-Insulator (SOI) process which is available to NVE both through AMI, Honeywell, and others. Problems of disturbs and non-uniform switching thresholds have been eliminated with this new development. This innovation will allow speeds of 10 nanoseconds as well as power levels as low as 0.1 microwatts. Its scalability will allow densities of 16 megabits per square centimeter using 0.15 micron lithography. The new cell architecture developed with SDT technology will have broad application in DoD military, space systems, MILSATCOM, and commercial space systems.The durability and low power of the MRAM developed will fill a need for this type of nonvolatile memory both in military and commercial satellite systems as well as missile systems. With no wear out mechanism, this memory will be used for both high speed main memory and nonvolatile buffer applications in artificial intelligence, image processing, radar, sonar signal processing, virtual reality, robotics, control systems, etc.

INFRAMAT CORP. 74 Batterson Park Road Farmington, CT 06032
Phone: PI: Topic#:	(860) 678-7561 Dr. Yide Zhang AF 01-035 Awarded: 06APR01
Title:	Nanostructured Ferrite for High Frequency Low Loss Power Converters
Abstract:	The Air Force seeks innovative processes for fabricating new ferrite materials exhibiting soft magnetic properties superior to conventional ferrites in high frequency DC-to-DC power converter applications. Ferrites have been used extensively as soft magnetic materials for five decades without major innovation despite significant power loss at elevated frequencies - the key factor limiting the miniaturization of electronic devices. Inframat Corporation proposes to demonstrate the feasibility of exploiting novel ferrite/Fe nanocomposite materials for significantly improved performance in power converter applications. High electric-resistive ferrite and Fe nanoparticles will be chemically synthesized using Inframat's economically viable aqueous solution method. The synthesized ferrite/Fe nanocomposite will be consolidated into desired magnetic components, tested, and compared with conventional ferrites. The design of the ferrite/Fe nanocomposite is based on exchange coupling, a quantum effect taking place between neighboring nanoparticles. The ferrite/Fe nanocomposite is expected to possess higher saturation magnetization, higher permeability, higher electrical resistivity, higher Curie temperature, and lower power loss at elevated frequencies than conventional ferrite materials. This advancement will be very important for the design of high power density DC converters. The proposed program is highly useful for developing a series of magnetic nanomaterials, which are expected to have a major impact on the electronics industry.Commercial applications of the proposed technology include: Power converters, microwave antenna or rectennas, high frequency electronic parts made by ferrites, such as inductors, chokes, sensors, core-shape transformers, ultra high radio frequency telecommunications, planar transformers, and hybrid circuits. Other applications include telecommunications, industrial electronics, computers, Entertainment, automotive, and multimedia equipment.

NANOSONIC, INC. P.O. Box 618 Christiansburg, VA 24068
Phone: PI: Topic#:	(540) 953-1785 Ms. Kristie Cooper AF 01-035 Awarded: 13APR01
Title:	Molecular Self-Assembly of Multilayer Low-Loss Ferrite Thin Films and Devices
Abstract:	This Air Force SBIR program would develop multilayered low-loss ferrite thin film materials for use in high frequency power electronic DC-DC voltage converters for next-generation small and lightweight electronic systems. The emphasis of the Phase I program is on the development of ferrite material synthesis methods capable of yielding ultrasoft superparamagnetic ferrite films with controlled high resistivities and low defect concentrations in order to avoid excess loss at high switching frequencies. NanoSonic proposes to use modified electrostatic self-assembly (ESA) methods that allow the incorporation of magnetic, nonmagnetic and other molecular precursors into precisely-dimensioned multilayered thin films. Recent research suggests the feasibility of such methods for the synthesis of ultrasoft, low-loss ferrite films several millimeters in thickness, and the ability to adjust magnetic properties through control over precursor chemistries and intermolecular arrangement within the film. Thin film growth, molecular orientation and morphology will be determined using spectroscopy, ellipsometry, and both force and electron microscopy. The resulting lumped electronic properties of a fabricated prototype thin film inductor will be measured using vibrating sample magnetometry, four-point resistance probe, and high frequency network analyzer instrumentation. NanoSonic would work with both Virginia Tech and a major U.S. aerospace electronic systems company to analyze material performance.Low-loss high-frequency thin film ferrite materials and devices have immediate and widespread military and commercial applications in power electronic DC-DC voltage converters for future small and lightweight electronic systems. At even higher frequencies, such ferrites have uses in aircraft and space-based antenna systems and microwave engineering devices, including isolators, rotators, circulators, phase shifters, mixers and parametric amplifiers.

ENGINEERED PLASTIC DESIGNS, INC. 19750 Weld County Road 7 Berthoud, CO 80513
Phone: PI: Topic#:	(970) 532-2268 Mr. John Dinsmoor AF 01-036 Awarded: 27APR01
Title:	Modular, Protective Container for Payload
Abstract:	Engineered Plastic Designs, Inc., supported by CSA Engineering, Inc. proposes to develop clean-room containerization concepts for minimizing exposure of both the secondary spacecraft and the full-up payload module to damaging shock, vibration, and temperature extremes resulting during ground transportation, while providing an efficient, safe means for integrating each secondary spacecraft with the adapter. Currently, spacecraft are packed into crates for shipping. These crates do not provide adequate protection from shock and vibration, nor are they reusable. Further, these containers do not provision for handling during the integration process. An innovative new approach, EPD's container design will incorporate a multifunctional support frame that, when used in conjunction with the external container shell will provide exceptional support and isolation to the spacecraft. Every spacecraft will have different mass and moment of inertia properties. The new container design will provide a platform that mitigates the shock and vibration exposure over a broad range of spacecraft size and weights. The resultant container system design will be economically manufactured to meet the future needs of the satellite launch community.The primary commercial application for this SBIR project will be to produce and sell a modular container system for ESPA. The potential market for handling and transportation of multi-functional spacecraft containers, with or without secondary payloads, is significant in terms of reduced cost, convenience and safety for spacecraft manufacturers and users. The benefits of such modular payload containers would apply to both civilian and military satellite launches, since they are launched from the same vehicles. Both are subject to the same high cost of failure, and therefore to the same requirements for high standards of safety and reliability.

RH LYON CORP. 691 Concord Avenue Cambridge, MA 02138
Phone: PI: Topic#:	(617) 864-7260 Dr. Richard H. Lyon AF 01-037 Awarded: 15MAR01
Title:	A CSEA Approach to Active Noise and Vibration Control
Abstract:	Active noise and vibration control (ANVC) has not lived up to its promise. Attempts in the 1930's had little success because of inability to control the phase in electronics and transducers. Digital processing appeared to offer a solution for dealing with phase and arriving at algorithms of a complexity that could not be realized by analog systems. There are applications where ANVC has achieved success; exhaust and inlet silencers, noise canceling headsets and active engine mounts, for example. But the promises of ANVC and investments made to develop products have been disappointing. One reason is technical. ANVC has been successful when the transfer functions between disturbance and receiver are simple. The systems through which the signals travel in most situations are complicated, and in detail, unknowable. Individual systems are complicated, and multiple realizations are variable. The estimation methods that ANVC has employed have not been able to deal with them. But, techniques developed for structural response estimation, machine diagnostics, and dereverberation offer new ways to achieve ANVC. We term this approach "Complex SEA/ANVC". This document proposes the first phase of a program to develop this method and to express it in software of commercial value.The research proposed here will allow the control of disturbances of particular types in complex structural and acoustical systems, such as large aerospace structures. The advances are made possible by signal processing means that have been developed for machine diagnostics and teleconferencing. These technologies rely on de-reverberation procedures that allow one to use a received signal and estimate the disturbance that produced it with good accuracy. That capability is also needed in feed-back ANVC systems. The algorithms to be developed in this research will find direct commercial application, either as a supplement to software packages in related areas such as SEA, or as integral components that extend the capabilities of existing ANVC products.

VIBRO-ACOUSTIC SCIENCES, INC. 12555 High Bluff Drive, Suite 310 San Diego, CA 92130
Phone: PI: Topic#:	(858) 350-0057 Mr. Paul Bremner AF 01-037 Awarded: 27APR01
Title:	Optimal Design of Active Noise Control Systems
Abstract:	In Phase I, Vibro-Acoustic Sciences will extend its proprietary Statistical Energy Analysis (SEA) code to estimate the statistics of phase for single input - single output transfer functions between launch vehicle fairing and payload acoustic volume. This is an extension of the preliminary research for AFRL on the same topic, conducted in 2000 by Vibro-Acoustic Science's collaborator and subcontratcor Prof. C.R Fuller of Virginia Tech. The statistcal phase prediction method will be experimentally validated with a simple laboratory experiment. The method will then be incorporated in Vibro-Acoustic Sciences' fairing active noise control model (developed in part under Air Force SBIR AF00-041) to theroretically predict how much active noise noise reduction is possible inside a fairing when the external acoustic excitation is partially space-correlated (ie. multiple statistcally independent sources) and when the internal payload acoustic field is reverberant.The method and experimental results developed in the first two phases of the SBIR program will be applicable to DoD and commercial launch vehicles and can be intergrated into the commercial software products already provided to these markets by Vibro-Acoustic Sciences. The successful application of the design method will reduce launch vehicle fairing acoustic levels and allow the use of more low cost COTS equipment on space vehicles.

ENVIRONMENTAL RESEARCH TECHNOLOGIES 3291 Cripple Creek Trail Boulder, CO 80305
Phone: PI: Topic#:	(303) 554-9764 Dr. Boris Khattatov AF 01-038 Awarded: 30MAY01
Title:	Advanced Modeling of the Ionosphere and Upper Atmosphere
Abstract:	Forecast skills of ionospheric operational models are negatively affected by the complexity of the underlying physical system and the necessity to specify a number of poorly known parameters. Hence these forecast models, including the PRISM used by the Air Force, are usually empirical, rather than the first-principles models. In addition, until recently ionospheric research suffered from lack and sparsity of observational data. This situation is changing dramatically owing mostly to advances in remote sensing of the ionosphere from space. Availability of vast amounts of observational data together with advances in computing power make it possible for the first time to apply data assimilation techniques to first-principles ionospheric models for improved forecasting and modeling of the ionosphere and the upper atmosphere. The primary goal of this Phase I research proposal is to identify data assimilation methods most suitable for use with ionospheric models and to implement the prototype data assimilation and forecast system for spatial distribution and time evolution of the ionospheric electron density. In Phase I we plan to design and test the algorithms using the Coupled Thermosphere Ionosphere Model (CTIM). The developed data assimilation algorithms and codes would be applicable to any physics-based global ionospheric model. In Phase II of this effort we will interface the developed system with the Coupled Thermosphere Ionosphere Plasmasphere Model (CTIPM) and the coupled thermosphere and ionosphere model CITFM used by the Air Force and create the practical real-time forecast system. Anticipated improvements in model's forecasts of ionospheric electron density profiles will be of immediate use for a number of military and civilian practical applications, particularly in communications and navigation. The proposed Phase I work will determine the fundamental data assimilation techniques needed to develop a practical operational electron density forecast system during the Phase II effort. In the private sector potential clients include companies operating cellular phone and pager networks, navigation infrastructure, in particular GPS receivers, other satellite-based communications, such as satellite-based wireless Internet service providers, and power grid companies. Development of practically feasible ionospheric forecast system will address these needs and open up radically new commercial and military applications in the field of wireless communications.

MISSION RESEARCH CORP. 735 State Street Santa Barbara, CA 93101
Phone: PI: Topic#:	(603) 891-0070 Jackie Schoendorf AF 01-038 Awarded: 23MAR20
Title:	Rapid Regional Ionospheric Modeling System (R-RIPS)
Abstract:	A key requirement for Air Force theater battle management is the ability to rapidly and accurately determine regional profiles of the upper atmosphere and ionosphere. To meet this requirement, we propose to develop the Rapid Regional Ionospheric Profiling System (R-RIPS). Current models are limited in their ability to meet global requirements for remote and rapid generation of upper atmospheric and ionospheric properties to aid the theater command. They are also limited in their ability to assimilate disparate data to yield real-time updates for regional applications. We propose an innovative application of current models and both existing and evolving data sources combined with learning algorithms (neural nets) to develop a Fully Equivalent Operational Model (FEOM). The proposed methodology for R-RIPS is built on innovative application of proven techniques. We will use data from existing ionosonde/digisonde stations, satellite sounding data from SSUSI & SSULI, DMSP particle detectors and two-frequency GPS signals combined with current ionospheric modeling capabilities to establish sub-global scale ionospheric characterization. Sub-gridding rules will then be established for mesoscale modeling. Learning algorithms will be used to develop critical correlation rules for data assimilation. The combination of real-world data and first-principles models will, in turn, be used to generate a FEOM, which is a model input-output response surface generating a rapidly converging series of low-dimensional correlation functions linking critical input parameters (e.g. F10.7, Ap, Lat/Lon, time, date, particle fluxes) with output density profiles. The FEOM can be initialized using a local two-frequency GPS receiver which generates line-of-sight total electron content. Updated data sets and first-principles modeling will be used to "nudge" the FEOM to increasing levels of accuracy as more information is made available. The FEOM approach has been applied to complex disturbed atmospheric chemistry and fluid dynamics problems and has proven model speed improvements exceeding 10^4 while retaining the fidelity of the original first-principles model. We propose to implement this innovative technique to solve the problem of rapid regional ionospheric profiling.The results of this proposed activity will allow rapid and more accurate regional assessments of upper atmospheric and ionospheric profiling for battle management requiring minimal computer resources. Commercial applications of this work include a broad range of space weather applications for satellite environments, orbital degradation, communications, advanced exploitation of GPS technology, radar ranging and design of advanced measurements and testing in space.

BECK ENGINEERING 3319 21st Ave NW Gig Harbor, WA 98335
Phone: PI: Topic#:	(253) 853-1703 Dr. Douglas S. Beck AF 01-039 Awarded: 29MAR01
Title:	Cooler for Space-Based Storage of Low-Temperature Cryogens
Abstract:	The Air Force needs systems capable of storing cryogens in space for longer than 20 years. We propose to develop enabling technology for long-term space-based storage of low-temperature (<35 K) cryogens. We propose to develop a compact and lightweight cooler that operates efficiently at cold temperatures. Our cooler will efficiently liquefy vapor boil-off from heat leakage to the cryogen, so the required power input to our cooler will be small, and the entire system (including solar panels) will be compact and lightweight. In Phase I, we will demonstrate operation of a breadboard cooler. In Phase II, we will optimize the design of our cooler for a particular space-based cooling application, and we will build and test an engineering design model cooler. In Phase III, we will license our cooler technology to other companies, and we will design, build, and sell our cooler for many applications in the Federal Government and the private sector.The commercial potential of our cooler technology is great because it can be applied to make current coolers efficient for cold load temperatures. We believe every company that is currently making coolers for spacecraft and terrestrial applications will want to license our technology, once we have demonstrated operation of a breadboard cooler in Phase I. Commercial applications of our cooler include cooling for: space-based stored cryogens for space-based lasers, orbit transfer vehicles, and propellant storage depots; space-based detectors; NASA propellant manufacturing on Mars; CMOS circuits; multi-chip modules; filterbanks; high-speed switches; stable oscillators for radar applications; filters for cellular phones; instrumentation for medical monitoring; and primary voltage standards.

WILSON COMPOSITE TECHNOLOGIES 1004 River Rock Drive, Suite 240 Folsom, CA 95630
Phone: PI: Topic#:	(916) 989-4812 Dr. Raymond Adsit AF 01-039 Awarded: 25MAY01
Title:	Long Term Cryogenic Fluid Storage
Abstract:	Advanced space system technologies require the development of lightweight, reliable and cost effective components. The liquid propulsion systems of these systems use cryogenic storage tanks. This proposed WCT program will research, design and develop a novel, light-weight, load bearing, possibly double walled but highly insulated composite tank that serves as propellant storage and also can be part of the overall support structure. After the insulative design concepts have been developed, the requisite analytical tools will be outlined to determine future design verification requirements. The proposed WCT cryogenic storage concept will be applicable to 20 year storage requirements and the design will be evaluated using computer life prediction techniques for thermal/ mechanical load environments, and then proven in the Phase I program by demonstration of basic concepts in the laboratory using cylindrical test hardware and in the Phase II program by the testing of a subscale demonstration model. The work plan will evaluate all of the potential storage tank and pressure vessel designs and insulation concepts which can be proved either singularly or in combination to assure meeting the technical objectives for this program of 20 year storage with 2% boil-off for liquid hydrogen over the 20 year period.The overall program will have developed the long term storage technology, both in materials and manufacturing processes, that can be readily applied to future advanced aerospace and satellite systems and commercial cryogenic ventures. The technology developed under this program will be immediately applicable to a wide range of launch vehicle, missile, satellite and other space programs. The future expendable, reusable and commercial launch vehicle programs will utilize liquid hydrogen and liquid oxygen as part of their propulsion systems. The performance requirements for these programs and the limited weight budget preclude the heavier, single function metallic structures for the propulsion tanks and inter-stage structure. The composite technology resulting from this effort can be used to provide a new generation of cryogenic resistant structure and materials fabrication concepts to the Air Force Space Program, Space Based Laser, BMDO and NASA launch vehicles, and applications in commercial industry. Cryogenic containment and handling structures could be readily fabricated using these designs and materials in the future. Insulation concepts can also be a key requirement of these designs. NASA X-33/ 34 projects and Air Force space projects are potential space related, missile intercept and launch vehicle applications and all of the U.S. prime contractors for commercial launch vehicles will also be candidates for this technology.

HYPERTECH SYSTEMS LLC 4 Dickens Court Irvine, CA 92612
Phone: PI: Topic#:	(949) 477-1019 Dr. David Slater AF 01-040 Awarded: 30APR01
Title:	Invariant Spectral/Spatial Techniques for Target Detection and Material Identification in Cluttered Backgrounds
Abstract:	In this project we will develop innovative algorithms for target detection and tracking, material identification, and atmospheric quantification. The algorithms will combine spectral and spatial information in hyperspectral images and will be applicable to the visible through short-wave infrared and thermal infrared spectral ranges. Targets will be represented using invariant physics-based spectral subspaces that describe target signatures over spatial and temporal variability in the illumination, atmospheric, and thermal environments. Background clutter will be represented using adaptive spectral subspaces that can represent arbitrary mixtures of several materials. Optimized algorithms will be derived that use the representations to detect, identify, and track low-contrast targets in unknown changing environments with substantial clutter. Since the algorithms are based on physical models, they can also be used to estimate parameters that describe the atmospheric conditions. The proposed algorithms are based on compact subspace representations and can be implemented efficiently. The algorithms will be evaluated using data from material and atmospheric databases and imagery from hyperspectral data collections. The new algorithms will significantly improve the capability of systems that process space-based electro-optical imagery. The new algorithms can be used in systems for surveillance, reconnaissance, and targeting applications. Related algorithms have important commercial applications in areas such as biomedicine, mining, and agricultural and environmental monitoring.

ONTARIO ENGINEERING INTERNATIONAL 3333 Harrision Street, Unit #6 Riverside, CA 92503
Phone: PI: Topic#:	(909) 283-5971 Mr. Russell Abbott AF 01-041 Awarded: 20APR01
Title:	Adaptive Computer System
Abstract:	In Phase 1, a scaleable Plug and Play interface will be developed and demonstrated in a multibus architecture with 4-8 modules. These modules can be added and removed at will without any reprogramming. Any failure or latch of any module will not stop bus communication with the remaining modules. A demonstration will be conducted simulating the addition, removal, and failure of various nodes In Phase 2, a Plug and Play interface will be developed capable of supporting an adaptive network architecture that can be implemented into a future Air Program spacecraft. This effort will include the fabrication of a simulated shaped micro-spacecraft with eight Plug and Play panels to demonstrate the capability of this interface. The micro-spacecraft structure will include adaptive cabling capable of reconfiguring itself to allow different subsystems to be added to the spacecraft. OEI has already developed the structure, panels and cabling interfaces for this cube shaped micro-spacecraft through previous research and development efforts. In Phase 3, this system will be promoted as a means to lower barriers of entry to providers of spacecraft components and subsystems by providing a common interface that eliminates the problem of proprietary bus architectures.The benefits of a Plug and Play interface will enable faster spacecraft integration thus reducing time and cost. Heritage subsystems can be equipped with front end Plug and Play modules to interface with any spacecraft reducing development costs. Dynamic reconfiguration will enable on-orbit assets to be updated by the addition of Plug and Play orbital replacement units.

RESEARCH SUPPORT INSTRUMENTS 4325-B Forbes Blvd Lanham, MD 20706
Phone: PI: Topic#:	(609) 903-3404 Dr. Jon R. Fox AF 01-042 Awarded: 17MAY01
Title:	A micro-machined energy-mass spectrograph for microsatellite applications
Abstract:	Research Support Instruments, Inc., with the aid of the Princeton University Photonics and Optoelectronic Materials (POEM) group, proposes the development of a micro-chip energy-mass spectrograph for space environment sensing aboard microsatellites. The micro-machined energy-mass spectrograph (M^2-EMS) is envisioned as a micro-miniaturized replacement for conventional particle energy and mass detection systems employed as space environment sensors. The M^2-EMS would employ pseudo-parallel electric and magnetic fields to separate particles by their energy:charge and mass:charge ratios. Micro-machined from Si wafers by anisotropic etching and outfitted with charged particle optic electrodes by standard lithographic techniques, the M^2-EMS energy-mass filter separator would be small and robust. Detection could be achieved by existing charge coupled-device technology. Because of the small scale, arrays of M^2-EMS could be constructed on a single wafer, and further parallel detection becomes possible. Funding is requested to design and construct such a device and perform an elementary proof-of-concept study.The micro-machined energy-mass spectrograph is envisioned as a micro-miniaturized replacement for conventional particle and energy mass detection systems in use in space applications and in industrial and laboratory plasma and vacuum systems. These miniature particle mass and energy detectors would be small enough to be integrated into micro-satellites, robust enough to be used in demanding hazard detection work, and inexpensive enough to be utilized in less demanding applications. The M^2-EMS would be versatile enough to be applied to the particle detection needs of satellite and terrestrial users.

NOVA RESEARCH, INC. 439 A Second Street Solvang, CA 93463
Phone: PI: Topic#:	(805) 693-9600 Mr. Mark A. Massie AF 01-043 Awarded: 11APR01
Title:	Space-Hardening and Hyperspectral Application of Microdewar-Based Surveillance Sensors
Abstract:	Through a concurrent Phase II SBIR program at Nova Research, Inc., investigators have developed an innovative modular cryogenic dewar/cooler/electronics package specifically designed for use with infrared focal plane arrays (FPA). The "Modular InfraRed Imaging Applications Development System" (MIRIADS) integrates the evacuated coldstage with FPA drive electronics by using the circuit board as part of the mechanical assembly for the vacuum enclosure. Internal layers of this "motherboard" are used as signal feedthrus, thus eliminating the reliability and microphonic issues associated with conventional vacuum feedthrus. This truly new concept permits signal digitization to occur within a few centimeters of the FPA itself, leading the way to further miniaturization and integration of the sensor/seeker package. Downstream processing is accomplished through the use of daughterboards which plug into the motherboard. Virtually any existing FPA device may be operated in this miniature system that permits detector cooling using either LN2 or a cryocooler. This Phase I program will produce revisions to the proven existing design to make it space flight qualifiable. In addition, Nova will work with SSG, Inc. to plan for the development of a miniature space-based grating imaging spectrometer system using the revised MIRIADS design. The high degree of sensor system programmability and integration afforded by this technique will permit the design and assembly of low cost, high performance instruments for use in space.

SSG, INC. 65 Jonspin Road Wilmington, MA 01887
Phone: PI: Topic#:	(978) 694-9991 Mr. Jay Schwartz AF 01-043 Awarded: 27APR01
Title:	Integration Concepts for Space IR Sensing Component Technologies
Abstract:	SSG proposes the development of a dual-octave, hyperspectral sensor, comprising a dual-band focal plane array and an innovative instrument concept for dual-band dispersive optics. The instrument concept proposed combines an innovative Grating Imaging Spectrometer (GIS) instrument concept with ultralightweight Silicon Carbide (SiC) materials to provide a novel optical system payload which addresses some of the critical requirements associated with next generation surveillance missions. SSG's innovative payload solution can be combined with other AFRL technology developments, specifically with high temperature, dual-band FPAs (DRS Technology) and compact, low-power drive electronics (Nova Research), to provide an instrument concept with several benefits: reduced mass from the application of SiC materials, an innovative, multifunction sensor design, and the benefits associated with the dual-band FPA and drive electronics developments; improved thermal stability from the material property advantages associated with SiC and from the elimination of dichroics or beamsplitters which is allowed by the dual-band IR FPA; and reduced costs associated with a reduced payload mass. In the work proposed here SSG will further develop the instrument concept, providing a conceptual opto-mechanical design, a detailed optical design, and a manufacturing plan which can be used to produce a prototype in Phase II. Interaction with AFRL, DRS, and Nova Research personnel will be critical to a successful effort.The hyperspectral imaging sensor concept proposed has a number of government and commercial applications in the area of remote sensing. Hyperspectral imaging for agri-business applications is a good example. In addition the silicon carbide materials used in our sensor can be applied directly to a number of commercial industrial needs, including lightweight, thermally stable components for semiconductor capital equipment applications.

CSA ENGINEERING, INC. 2565 Leghorn Street Mountain View, CA 94043
Phone: PI: Topic#:	(650) 210-9000 Mr. Eric M. Flint AF 01-044 Awarded: 29MAR01
Title:	Affordable On-Orbit Demonstration of Very Flexible Large Space Structures Control and Pointing
Abstract:	CSA Engineering proposes the design, development, qualification, and on-orbit use of a demonstrator of control and pointing for a scaled very flexible large space structure system architecture intended to simulate the PowerSail. On-orbit testing is the only way to properly capture the dynamic and related attitude control behavior of tension dependent structures such as tethers and membranes that dominate the structure of the PowerSail and many other future space mission concepts. The major proposed development will achieve this in an affordable manner. This will be done by using a launch vehicles upper stage to simulate the PowerSail's tethered host structure as well as providing additional support like telemetry and power. In addition to developing and flying the on-orbit demonstrator and supporting avionics, CSA Engineering intends to demonstrate practical attitude control algorithms, structural vibration mitigation and damping approaches, and alternative/supplementary attitude control hardware all intended to reduce on-orbit station keeping fuel requirements. Activities in Phase I will concentrate on establishing the feasibility of the proposed effort with regard to technical compatibility and cost and demonstrating the functionality of several key components. Phase II effort will concentrate on taking the proposed concept to flight.The proposed effort is directly targeted at supporting the needs of the PowerSail project to find an innovative and affordable way to reduce programmatic risk through the demonstration of on-orbit attitude control and pointing of large very flexible structures. The lessons learned from this experiment are expected to be extremely beneficial to the PowerSail as well as other similar mission concepts based on gossamer or membrane structures which CSA Engineering would be well positioned to support. We also expect an additional market for facilitating affordable on-orbit testing of larger structures and deployment methods for major aerospace companies and a market to develop for systems for actuating solar sail vanes and trim tabs.

PLANNING SYSTEMS, INC. 7923 Jones Branch Drive McLean, VA 22102
Phone: PI: Topic#:	(321) 768-6500 Mr. Lawrence D. Davis AF 01-044 Awarded: 16APR01
Title:	Control and Pointing of Very Flexible Large Space Structures
Abstract:	The extreme flexibility of proposed ultra-lightweight spacecraft, such as the Air Force's PowerSail, will require a new generation of attitude control systems (ACS) that can accommodate low-frequency flexible dynamics within the pointing control bandwidth. In addition, as spacecraft designs continue to reduce mass density, it will become increasingly difficult to construct and validate dynamic models on the ground that are of sufficient fidelity to use for traditional fixed-gain control design. To meet these challenges, we will show the feasibility of an adaptive, attitude control design approach that works during flight to autonomously identify the system dynamics affecting the control bandwidth, then design feedback control laws to achieve predefined performance and stability criteria. This approach is an extension of our Frequency Domain Expert (FDE) control algorithm, which is currently being demonstrated on the Space Station Freedom as part of the Middeck Active Control Experiment (MACE-II).We intend to partner with the Air Force Research Laboratory (AFRL) to inject this technology into future Air Force programs, beginning with the PowerSail technology demonstration program. Once the technology has been demonstrated successfully on a flight experiment, operational uses both for the integrated, deployable PowerSail technology and for the adaptive attitude control system technology will be exploited. In parallel with this DOD-related effort, a smaller effort will be launched in the area of industrial servo-controllers in Phase II. The unique capabilities of the proposed technologies will enable the implementation of an automatic, coordinated, multi-axis servo control system embodied in a stand-alone control computer.

AEROASTRO, INC. 520 Huntmar Park Drive Herndon, VA 20170
Phone: PI: Topic#:	(617)451-8630 Mr. Joel Pedlikin AF 01-045 Awarded: 30MAR01
Title:	A Modular Satellite Bus Architecture to Enable Rapid Configuration and On-Orbit Servicing
Abstract:	Future satellite architectures must readily support the on-orbit maintenance and servicing that is vital for maintaining and dynamically reconfiguring both commercial and military satellites during orbital operation. A well-founded architectural design must also address the need to reduce costs associated with satellite development, fabrication, and operation; improve flexibility in response to mission needs; improve modularity; and enhance survivability. The advent of satellite clusters and constellations for communications and reconnaissance purposes places a premium on microsatellites that are small (multiple vehicles per launch), low cost, easily (and dynamically) reconfigurable, on-orbit serviceable, and simple to manufacture in quantity. To solve the problems related to on-orbit servicing, dynamic reconfiguration, and manufacturing, AeroAstro proposes to investigate during Phase I a satellite bus architecture that features modular mechanical and electrical elements coupled with standardized, non-proprietary interfaces and protocols. When applied to microsatellites, this design will result in a highly capable, reconfigurable, and serviceable spacecraft that is built around a set of extruded metal "building blocks" (a frame) and a core module of extensible plug-and-play electronics. Phase I will focus on a plug-and-play mechanical and system architecture that reduces design complexity, increases vehicle modularity, and improves the capacity for on-orbit servicing. Three important factors driving the design of microsatellites today are (1) the drive to enable routine on-orbit maintenance or repair on space vehicles, (2) the need for on-orbit satellite reconfiguration in response to changing mission dynamics, and (3) the need to reduce the cost of assembling microsatellites that are intended to function in clusters or constellations. A solution to these problems requires a design for a microsatellite architecture that is flexible, modular, based on commercially available standards and interfaces, and that takes advantage of plug-and-play concepts now widely used throughout the personal computer industry. AeroAstro proposes to address these problems by designing and developing (Phase I) and then demonstrating (Phase II) a prototype microsatellite architecture built around modular mechanical (metallic) frames and modular electronic elements that function in conjunction with standardized, non-proprietary interfaces. Both the military and commercial satellite communities will benefit from (1) a simple, standardized design for satellite structural and electrical architectures, interfaces, and protocols; (2) increased vehicle modularity; (3) the capability for dynamic reconfiguration of on-board systems to meet shifting mission requirements; (4) improved on-orbit maintenance and repair capability; and (5) reduced costs for manufacturing and assembling microsatellites intended for use in clusters or constellations.

MICROCOSM, INC. 401 Coral Circle El Segundo, CA 90245
Phone: PI: Topic#:	(310) 726-4100 Dr. James R. Wertz AF 01-046 Awarded: 13APR01
Title:	Modular, Miniature, Reconfigurable Spacecraft Attitude Determination and Control Subsystem with Standard Interfaces
Abstract:	The lack of interface standards for information exchange among spacecraft subsystems/avionics together with non-standardized, mission-unique GN&C architectures have resulted in high cost spacecraft systems with long integration and test times and increased flight operational complexity. Industry is in need of a solution to minimize cost, shorten development schedule and simplify design. Microcosm and Swales Aerospace propose to develop an innovative spacecraft GN&C architecture and integration technology that enable the spacecraft community to architect a common or universal framework allowing plug and play (interchangeability) of GN&C components to be accomplished in a unified manner. The universal framework facilitates software commonality and flight code reusability, thereby allowing effective cost minimization. Component interchangeability in a unified manner facilitates universal integration and interoperability between GN&C components at both software and hardware levels, thereby providing a more robust integration environment subject to future system evolution. The Phase I effort will focus on the following items: 1) development of interface standards between the flight data bus and GN&C peripherals; 2) definition of common software modules and/or architectures that support the plug-and-play capability; and 3) identification of relevant commercial off-the-shelf technologies that support the implementation of the proposed concept in Phases II and III. The commercial application of the proposed system is for spacecraft that could make use of a low-cost, modular ACS system with standardized interfaces and easily interchangeable components, to reduce the non-recurring costs involved with a brand new ACS system development effort. The GN&C interface standards may also be extendable to other vehicles such as missiles, aircraft, or automobiles. Reuse of GN&C flight code is another potential commercial application for this system.

SPACE PHOTONICS, INC. 700 Research Center Blvd. Fayetteville, AR 72701
Phone: PI: Topic#:	(501) 575-5316 Mr. Charles H. Chalfant AF 01-046 Awarded: 11APR01
Title:	A Modular Miniature Satellite Laser Communications Transceiver
Abstract:	For this Phase I SBIR proposal, Space Photonics puts forth highly innovative solutions for multi-access satellite clusters using our proposed miniature modular free-space laser communications transceiver subsystem. By virtue of our unique device and application specific designs, our laser cross-link transceivers provide wide field-of-view access without the need for the power hungry gimbaling that is typically required for accurate acquisition and tracking. Additionally, the transceiver provides for enhanced utility for open architecture implementations, optimized link power budget efficiency, and a straightforward modular interface designed for satellite power and data bus interfaces. Our proposed techniques and device designs were not possible just a few years ago, but with the most recent advances in device fabrication technology, our idea can be implemented and provide enormous value to laser cross-link systems.Our planned laser communications product line has enormous market potential, since to our knowledge, no such product has ever been conceptualized. The devices, firmware, software, and subsystems that will make up this product line will provide us with a large market opportunity in both the Government and commercial sectors. We anticipate broad use of these products in the last mile metro-area network markets and the rapidly growing multi-satellite applications market.

SY TECHNOLOGY, INC. 5170 N. Sepulveda Blvd., Suite 240 Sherman Oaks, CA 91403
Phone: PI: Topic#:	(256) 922-9095 Dr. Larry Pezzaniti AF 01-047 Selected for Award
Title:	Small Integration IR Imaging Polarimeter for Optical Stand-off Detection
Abstract:	Applications of IR imaging polarimetry include detection of military targets in clutter, de-mining missions, ice detection on aircraft, roads and bridges, crop monitoring and remote sensing. Key technologies are now sufficiently mature to consider a robust, integrated optical imaging polarimeter, which operates at video rates. SY Technology, Inc proposes during the Phase I effort to design an IR (8-12 um) polarization imager. The proposed imaging polarimeter design involves pixilated polarization optics overlaid onto a commercially available IR focal plane array. The device would generate a set of four interlaced images, each measuring a different property of the scene's polarization state. The images would be manipulated to yield complete polarization information about each field point across the image. SY Technology would fabricate single pixel versions of the polarization optics in order to demonstrate the feasibility of the proposed design approach. The proven design will be extended to an array during the Phase II. It is believed that the imaging polarimeter proposed here will lead to lightweight autonomous imaging polarimeter that can be used for remote applications such as surveillance and reconnaissance from space based measurement platforms. It is anticipated that an IR imaging polarimeter will significantly enhance target detection on a wide variety of military seekers. Ice detection, humanitarian de-mining, remote sensing, and medical imaging applications are all potential commercial applications of an IR chip based imaging polarimeter.

MICROCOSM, INC. 401 Coral Circle El Segundo, CA 90245
Phone: PI: Topic#:	(310) 726-4100 Dr. James R. Wertz AF 01-048 Awarded: 30MAR01
Title:	In-Space Testing of Satellite Servicing and Inspection Elements
Abstract:	By building on technology elements funded elsewhere, Microcosm proposes to develop an inspection and servicing architecture and test key components of that architecture in space by the end of Phase II, all within Phases I and II budgets. Phase I is primarily a systems study concentrating on three principal issues: (1) system engineering trades leading to the development of an efficient, flexible architecture, (2) the benefits of on-orbit inspection and servicing to reduce cost and enable new missions, and (3) definition of the in-space test in sufficient detail to ensure that it can be completed within the scope of a Phase II SBIR. This substantial step is made possible by leveraging recently awarded and related NASA and DARPA SBIRs, Microcosm's current autonomous GN&C and expert control systems, and Michigan Aerospace's autonomous docking system, and making use of a free test flight of Microcosm's Scorpius low-cost launch system currently undergoing development and flight tests. The system level technologies developed here are critical to the Air Force Space Control mission and could be of substantial benefit to both NASA and commercial users. The in-space system testing represents a major, near-term step in making this technology available to the space community.There is great potential for this technology to substantially lower the cost and extend the life of LEO science and defense related missions as well as GEO communications satellites. The lifetime of a LEO satellite is limited primarily by atmospheric drag. A virtually unlimited supply of fuel could be transferred to LEO satellites, indefinitely, for stationkeeping purposes. High priced defense programs (e.g. SBIRS Low and SBL) and science missions (e.g. HST and TOPEX) would no longer be consumables limited if they could support satellite docking, refueling, and component replacement. GEO satellites pay a high premium for stationkeeping fuel. If GEO satellites where able to refuel, their payload mass fraction could be increased substantially at launch. This option is particularly attractive due to the relatively large number of launches per year into GTO. Re-fueling missions could be made small enough to fit as a secondary payload aboard the ASAP ring of the Ariane 5, for example, further increasing the cost efficacy of on-orbit servicing.

PRINCETON SATELLITE SYSTEMS 33 Witherspoon Street Princeton, NJ 08542
Phone: PI: Topic#:	(505) 846-4287 Ms. Margarita Brito AF 01-048 Awarded: 27APR01
Title:	Autonomous Satellite Servicing to Increase Effective Mission Life
Abstract:	There is a growing interest in autonomous on-orbit servicing of satellites among military and commercial segments. Autonomous on-orbit servicing can increase mission flexibility and mission life. Additionaly, there is a potential for reductions in life cycle cost. This proposal is for a novel robotics vision based autonomous rendezvous and docking system for military and commercial satellites. The Satellite Servicing Vehicle (SSV) is capable of docking with both cooperative and uncooperative targets. When the target is cooperative, the system uses an intersatellite link (ISL) to facilitate coordination between the two vehicles. Additionally, the SSV is capable of inspecting the target satellite by using the vision system used for docking. The software architecture is based on the PSS ObjectAgent agent-based distributed control software architecture.Increase mission flexibility, increased mission life and reduced life cycle costs.

SCIENTIFIC SYSTEMS CO., INC. 500 West Cummings Park, Suite 3000 Woburn, MA 01801
Phone: PI: Topic#:	(781) 933-5355 Dr. Pablo O. Arambel AF 01-048 Awarded: 27APR01
Title:	Autonomous Fault-Tolerant Guidance, Navigation and Control System for Automated Rendezvous and Docking
Abstract:	An essential element of autonomous satellite servicing is a fully Autonomous Rendezvous and Docking (ARD) system. Precision ARD capability is required for the DARPA-ASTRO, NASA-MSR, and International Space Station missions, among others. We propose to develop a hierarchical ARD system with a top-level supervisory controller and two low-level interconnected subsystems: (i) failure detection, identification, and state estimation (FDISE) subsystem, and (ii) guidance, navigation and control (GNC) subsystem. An Interacting Multiple-Model Kalman filter is used for failure detection, identification, and navigational filtering of video guidance system, laser radar sensor, and other sensor data. The GNC subsystem consists of a suite of controllers designed to meet safety and performance requirements. The top-level supervisor coordinates sensor management, GNC mode switching, fault-tolerant reconfiguration and other event-driven functionalities. Phase I work will demonstrate feasibility through a detailed simulation. A hardware-in-the-loop testbed for supervised autonomy will be developed in Phase II. NASA-JPL GNC group under the guidance of Dr. Fred Hadaegh will provide technical support during all Phases of the project based on their previous and ongoing work for the Mars Sample Return mission.Autonomous rendezvous and docking system is directly applicable to satellite servicing and re-supply. Vision-based GNC are applicable to underwater exploration and mining, autonomous automobiles, manufacturing, telerobotics, electronic toys, and cinematography. These applications represent a vast untapped market for the technologies developed.

DELTA VELOCITY CORP. 932 Edwards Ferry Road, Suite 14 Leesburg, VA 20176
Phone: PI: Topic#:	(703) 927-9196 Mr. Joseph Padavano AF 01-049 Awarded: 10MAY01
Title:	Launch Vehicle Fairing with Integral Vibroacoustic Attenuation
Abstract:	The proposed effort will demonstrate the feasibility of fabricating a launch vehicle payload fairing using a novel method for attenuating structural response to vibroacoustic loads. The proposed effort incorporates an innovative method of fabricating composite structures and increasing the surface density of the skin panels without degrading launch vehicle performance. The attenuation method equals or betters the performance of conventional acoustic blankets in all frequency ranges, and is particularly effective at frequencies below 500 Hz.Traditional payload fairing acoustic blankets are not effective at reducing acoustic levels under about 500 Hz. A new method of attenuation is proposed which will reduce these low-frequency launch loads with minimal or no launch vehicle performance impact. The low mass impact of the attenuation method will improve launch vehicle performance and the more benign environments will allow a reduction in the cost to develop and qualify spacecraft. This attenuation concept is enabled by an innovative, low cost method for fabricating graphite composite payload fairing structures. The concept is applicable to all launch vehicle structures and large panels on spacecraft in addition to payload fairings.

FOSTER-MILLER, INC. 350 Second Ave. Waltham, MA 02451
Phone: PI: Topic#:	(781) 622-5504 Mr. Thomas Campbell AF 01-049 Awarded: 17MAY01
Title:	Multifunctional Composite Grid Stiffened Launch Vehicle Fairings
Abstract:	Payload fairings are a critical cost and performance driver for launch vehicles. Grid stiffened construction is an efficient alternative to current composite core designs. Foster-Miller has assembled an expert team, including The Boeing Company and Alliant TechSystems, to evaluate options, develop, analyze and design a multifunctional, grid stiffened structure Key advantages to the Foster-Miller team approach include the following:  Out of autoclave processing using Ultrasonic Tape Lamination (UTL), which enables consideration of both standard oven cure resins and the most advanced toughened epoxies which usually require an autoclave.  Integral damping with novel material and configuration options  Low shock separation - with multiple system and adhesive options  Embedded wiring to deliver power for separation device activation Foster-Miller is an innovative leader in the development of new composites designs and technologies. Alliant is the original developer of fiber placement and continues to be the leading innovator of its use in many applications, specifically including composite isogrids. The Boeing Company is one of the largest launch vehicle producers and the ideal partner to facilitate consideration and integration of the developed technology. (P-01426) The proposed program will yield development of a new, cost effective grid stiffened launch vehicle shroud system. There is high potential for significant cost and weight reduction on existing composite systems with options for reduced acoustic and separation loads. All these factors are highly desirable to serve a spacecraft launch market that includes military missions and a much larger commercial business sector.

21ST CENTURY SYSTEMS, INC. 427 South 166th Street Omaha, NE 68118
Phone: PI: Topic#:	(303) 346-9402 Mr. Stuart L. Aldridge AF 01-053 Awarded: 09MAY01
Title:	Satellite Operator Decision Aid And Training System (SODATS)
Abstract:	In response to Small Business Innovative Research solicitation AF01-053, 21CSI is pleased to propose the development of a proof-of-concept software decision aid for satellite command composition. Our decision aid, the Satellite Operator Decision Aid and Training System (SODATS), will be built from the bottom up to support both operator training and operational usage. It will employ intelligent agent technology to generate both command package recommendations and their underlying rationale. We propose to focus our development activity on the needs of the Space Based InfraRed Systems Low component (SBIRS Low), starting with the use of existing SBIRS Low Flight Demonstration System command structures.This SBIR will culminate in an integrated SODATS software package, which will assist satellite operator teams to deal with command composition. This will be a unique product. Many commercial applications, which require their own command composition, would benefit strongly from the SODATS concept: power plants, automated, flexible manufacturing factories, intelligent transportation and communications, air traffic control, space exploration, financial trading (traditional and online) and others. The SODATS product will be delivered through 21CSI's open EMDA architecture. Beyond the SODATS core product, transition of the decision support system (DSS) technology itself too will be of a very significant potential. DSS agents have wide potential applicability to just about every industry, which involves humans in the loop. Our first commercial, non-military product incorporating this technology (namely, a SODATS agent-based decision support package, for command composition) will likely be part of a decision support tool for risk assessment of financial, credit and insurance transactions (an industry which has its own rich command language). The tool will plug into the existing online resources, including trading systems, credit bureau databases, stock monitoring systems and others. The tool will be used both for support of decisionmaking and for distributed training.

CYBERNET SYSTEMS CORP. 727 Airport Boulevard Ann Arbor, MI 48108
Phone: PI: Topic#:	(734) 668-2567 Dr. Charles J. Cohen AF 01-053 Awarded: 13APR01
Title:	Training Environment for Satellite Command Composition
Abstract:	The vast amount of knowledge on human information processing and performance has not been completely utilized for solving real world problems. A typical satellite control system uses 500 to 1000 commandlets (fragmentary commands), which must be optimally put together efficient and effective satellite control. Also, since a satellite can be controlled from many different places, with learning and training also spread across the country (if not world), working in multiple task environments leads to increased workload, and demands superior performance skills both in stressful and non-stressful situations. With a systematic and logical approach, existing cognitive theories can be unified with advances in computer technology to develop scenario-based assessment and optimization programs for satellite control. To accomplish this task, Cybernet will build upon our past success in individual training performance to create a new system that will allow the measurement and the `Why?' of team performance. This system will provide not only for the capability of advanced team training in complicated and stressful environments, but also the optimization of this training and creation of composite commands from commandlets.Cybernet has developed a massive multi-player simulation technology for air, sea and land game and simulation play. While this technology was originally developed for low cost government simulation for training, Cybernet plans to adapt the technology to revolutionize the consumer network gaming and flight simulator industry.

CHI SYSTEMS, INC. Gwynedd Office Park, 716 N. Bethlehem Pike, Ste 30 Lower Gwynedd, PA 19002
Phone: PI: Topic#:	(407) 249-1656 Dr. Kelly Neville AF 01-054 Awarded: 12APR01
Title:	A Decision Aid for a Surveillance Satellite Crew Shift Supervisor
Abstract:	To be effective in today's threat environment, the Air Force's Global Engagement doctrine asserts that personnel be responsive, innovative, adaptable, and agile. This will be particularly important for the Space-Based Infrared System (SBIRS) Low Crew Chief. The SBIRS Low Crew Chief will have to manage a team with frequently changing personnel, groups of personnel with different specializations, and a new mission - time critical target tracking. To assist the Crew Chief, we propose to develop a decision and training support system called Adaptive Decision Enabling and Performance Tracking (ADEPT). This system will be designed to support the Crew Chief in day-to-day operations and training exercises. It will utilize intelligent agent technology to monitor and assess individual crewmember performance and team processes, and, based on its assessments, will provide guidance to help the Crew Chief manage the SBIRS Low team. For example, ADEPT will provide advice in real-time about how to allocate attention across different SBIRS Low subteams, how to manage their team-level activities and responses to various situations, and what feedback and guidance to provide.ADEPT will be developed as a decision and training aid for the SBIRS Low operations center, which includes Satellite Operations, Missile Warning, Ground Systems, and Intelligence cells. ADEPT may be of value to the training and operations of any organization in which any of these functions is performed. In particular, it could be used by Navy, Army, and National Reconnaissance Office (NRO) satellite control organizations. Further, it may be adapted to support the training of personnel as they prepare to join an SBIRS operations crew. In addition, ADEPT may be valuable to the civil satellite control agencies National Aeronautics and Space Administration (NASA) and the National Oceanic and Atmospheric Administration (NOAA). In particular, NASA and NOAA satellite control personnel have many responsibilities that mirror the responsibilities of satellite operations personnel in the SBIRS Low crew and may therefore benefit from ADEPT's capabilities. Finally, the task performance and instructional content to be contained within the ADEPT agents could be used to help various defense, intelligence, and civil satellite control agencies develop more standardized procedures and move toward the goal of cost reduction through improved consolidation (Government Accounting Office, 2 May 1996). It is likely that the emphasis of this effort on team performance and team processes will result in an extension of existing decision and performance support technologies that is especially important in light of the modern trend, made possible by advances in information and communication technologies, toward increasingly large and complex teams. The resulting extension to decision and performance support technologies, coupled with consulting services, could be used to provide solutions to a wide range of corporate teams. In addition, ADEPT will contain much about how satellite system operators of varying levels of expertise perform their jobs and will identify difficulties they have in performing those jobs. Because this information will be represented by the iGEN model building interface in an easy-to-follow and structured way, CHI Systems and others will be able to use it to derive training documentation enhancements and to identify ways to improve SBIRS Low systems and processes.

SONALYSTS, INC. 215 Parkway North, P.O. Box 280 Waterford, CT 06385
Phone: PI: Topic#:	(860) 442-4355 Dr. James E. McCarthy AF 01-054 Awarded: 02MAY01
Title:	A Decision Aid for a Surveillance Satellite Crew Shift Supervisor
Abstract:	The Phase I effort will focus on development methodologies for relating Surveillance Satellite Crew individual, team, and inter-team tasks, performance criteria, learning objectives, learning objective mastery, measures of effectiveness (MOEs), and measures of performance (MOPs)to overall Unit mission essential task lists (METLs) and satellite operations core competencies. Phase I efforts also will result in a proof-of-concept Satellite Crew Shift Supervisor decision aid demonstration. Sonalysts' proposed approach will leverage several years of Navy team training research and a substantial infrastructure of existing software developed for the Training Management Module (TMM) and Afloat Training Exercise and Management System (ATEAMS) as a starting point. Recognizing that differences between Surveillance Satellites and Navy Combat Systems are significant, there are substantial similarities in task organization and decision aid objectives that can be explored cost-effectively under this SBIR Phase I effort. Phase II efforts will produce a full demonstration of a prototype decision aid to support a shift supervisor with a minimum of 15 subordinate crewmembers. Methods for assessing the decision aid features and interfaces to an existing satellite system or prototype will be developed. Sonalysts approach to Phase II efforts will be coordinated with Satellite Operations Training System (SOTS) common architecture and Distributed Mission Training-Space (DMT-S), Crew Trainer Emulator (CTE), or other Space Training, Education and Exercise (STEDE) concepts.Development of a Surveillance Satellite Crew Shift Supervisor decision aid fits directly into the SOTS common architecture concept's Space Exercise and Training Management component and is also common with the DMT-S structure. The framework and decision aid technology will support training management from the AETC school structure to legacy satellite systems. This research has a clear and direct impact for cost, schedule, and performance risk reduction for future systems such as the Space-Based Infrared Reconnaissance System (SBIRS). In addition, this effort has wider military, government, commercial, and educational application through consistency with the Office of the Secretary of Defense (OSD) Advanced Distributed Learning (ADL) Initiative.

STOTTLER HENKE ASSOC., INC. 1660 So. Amphlett Blvd., Suite 350 San Mateo, CA 94402
Phone: PI: Topic#:	(650) 655-7242 Dr. John L. Mohammed AF 01-055 Awarded: 26APR01
Title:	SatConPlan: A Satellite Pre-Pass Contact Planning Aid for Operations Support and Training.
Abstract:	Future plans in both the military and commercial sectors call for increased use of satellite constellations in low earth orbit. These systems significantly increase the burden for ground-based system management because more satellites must be managed, and each satellite is in view for only brief periods of time. It will be essential to ensure that ground station hardware and personnel are fully prepared to exploit every contact opportunity. SHAI, with our contractor Honeywell Technology Solutions, Inc., proposes to develop SatConPlan, a pre-pass planning aid that will improve the efficacy and accuracy of preparations for satellite contacts, and that will enable improved training for satellite operators. SatConPlan will combine techniques from Intelligent Agent Technology, Model-Based Reasoning, Planning and Scheduling, and Intelligent Tutoring Systems to support distributed teams of operators during both operations and training. Honeywell Technology Solutions, Inc., as a highly successful provider of satellite operations software and services, will contribute expertise regarding satellite pre-pass planning and operations. The goals of the Phase I research are to thoroughly analyse the satellite pre-pass planning domain, develop knowledge representations and reasoning techniques to codify contact preparation processes and procedures, and prove the feasibility of our approach by building a proof-of-concept prototype. The proposed technology will directly benefit both military (e.g., SBIRS-Low) and commercial LEO constellations, reducing operations risk as well as operations and training costs.

SYTRONICS, INC. 4433 Dayton-Xenia Road, Building 1 Dayton, OH 45432
Phone: PI: Topic#:	(937) 431-6121 Mr. John Friskie AF 01-055 Awarded: 02MAY01
Title:	A Satellite Pre-Pass Contact Support Aid
Abstract:	SYTRONICS proposes a Satellite Pre-pass Organization Tool (SPOT) which applies state-of-the-art agenting technology upon a solid technical/operational foundation--the High-Level Integrated Team Training Environment (HILITE), developed for AFRL/HE under a previous SYTRONICS Program. SPOT provides the control, visualization, and agent capability for decision-aid functionality; the ability to simulate and test operational options for training and for pre-pass decision-making; and a HLA (High-level architecture) interface to all assets necessary for operations or training--a Distributed Mission Training (DMT) capability. The Phase I objectives are: (1) define requirements to specify initial performance and assessment measures to support the satellite pre-pass contact effectiveness; (2) develop a top-level architecture design to the extent necessary to develop an early prototype, perform experimental and analytical feasibility assessments, and form a sound design basis for Phase II; (3) assess feasibility through simulation and analysis to establish performance, implementation, and cost; and (4) assess commercial product potential to determine markets, competitors, and collaborators for SPOT. The Phase I results will be the requirements, architecture design, simulation and analysis results, and a preliminary commercialization plan, as well as a demonstration of the simulation-proven feasibility. These results will provide a solid foundation for Phase II.SPOT will generally support all kinds of satellite pre-pass planning and decision tradeoff analyses. It will find use in myriad military satellite planning operations. Its compatibility with, and interface to the DMT and HLA infrastructures, will make it a practical and useful training system as well. In commercial enterprises, as more commerce migrates into space, it will become a highly-desired commercial satellite pre-pass organizer and trainer as well.

STOTTLER HENKE ASSOC., INC. 1660 So. Amphlett Blvd., Suite 350 San Mateo, CA 94402
Phone: PI: Topic#:	(650) 655-7242 Dr. John L. Mohammed AF 01-056 Awarded: 26APR01
Title:	SatConReport: A Satellite Post-Pass Debriefing Aid for Operations Support and Training
Abstract:	To minimize operations costs, mission analysts and planners are not usually present during satellite contacts. Nonetheless, analysts must be apprised of all key information gained, especially regarding anomalous events. SHAI, with our contractor Honeywell Technology Solutions, Inc., proposes to develop SatConReport, a post-pass debriefing aid that will assist satellite operators to efficiently prepare comprehensive and accurate satellite contact reports. SatConReport will also enable improved simulation-based training for satellite operators. SatConReport will combine techniques from Intelligent Agent Technology, Case-Based Reasoning (CBR), Model-Based Reasoning (MBR), and Intelligent Tutoring Systems (ITS) to support distributed teams of operators during both operations and training. Agent technology will enable fusion of information from distributed sources, and realistic simulation-based training. CBR and MBR will enable report generation to be goal-directed and hypothesis driven. ITS technology will tailor training to each operator's skill level. Honeywell Technology Solutions, Inc., as a highly successful provider of satellite operations software and services, will contribute expertise regarding satellite post-pass debrief procedures. The goals of the Phase I research are to thoroughly analyse the satellite post-pass debriefing task, develop knowledge representations and reasoning techniques to codify contact debrief procedures, and prove the feasibility of our approach by building a proof-of-concept prototype. The proposed technology will directly benefit both military (e.g., SBIRS-Low) and commercial LEO constellations, reducing operations risk as well as operations and training costs.

SYTRONICS, INC. 4433 Dayton-Xenia Road, Building 1 Dayton, OH 45432
Phone: PI: Topic#:	(937) 431-6121 Mr. John Friskie AF 01-056 Awarded: 07MAY01
Title:	A Satellite Operations Debrief Aid
Abstract:	SYTRONICS proposes a Satellite Operations Review Tool (SORT) system which applies state-of-the-art agenting technology upon a solid technical/operational foundation--the High-Level Integrated Team Training Environment (HILITE), developed for AFRL/HE under a previous SYTRONICS Program. SPOT provides a post-pass analysis decision aid with control, visualization, and agent capability for post-pass analysis and reporting; the ability to simulate and test operational impacts of the pass and explore alternatives; and a HLA or local interface to all assets necessary for operations or training--a Distributed Mission Training (DMT) capability. The Phase I objectives are: (1) define requirements to specify performance and assessment measures for satellite post-pass review operations; (2) develop a top-level architecture design to the extent necessary to implement an early prototype, perform feasibility assessments, and form a design basis for Phase II; (3) assess feasibility through simulation and analysis to establish performance, implementation, and cost feasibility through simulation and analysis; and (4) assess commercial product potential to determine markets, competitors, and collaborators for SPOT. The Phase I results will be the requirements, architecture design, simulation and analysis results, and a preliminary commercialization plan, as well as a demonstration of the simulation-proven feasibility. These results will provide a solid foundation for Phase II.SORT will serve all the needs of the military for satellite post-pass analysis decision support and has the ability to generally support all types of satellite post-pass analysis and decision tradeoff analyses. Its inherent compatibility with, and interface to the DMT and HLA infrastructures will make it a practical and useful training system as well. In commercial applications, as more commerce migrates into space, it will become a highly-desired commercial satellite post-pass analyzer and trainer.

ALAMEDA APPLIED SCIENCES CORP. 2235 Polvorosa Ave, Suite 230 San Leandro, CA 94577
Phone: PI: Topic#:	(510) 483-4156 Dr. Jochen Schein AF 01-058 Awarded: 11APR01
Title:	Improved Coatings for Helmet Mounted Display Visors using Filtered Cathodic Arc Plasma Deposition
Abstract:	Alameda Applied Sciences Corporation (AASC) proposes to develop and commercialize stable, more durable and less expensive optical multi-layer coatings that can turn a visor into a display screen for helmet mounted display devices, with minimal impact on the pilot's overall visual acuity. The innovation proposed is to use filtered cathodic arc plasmas to deposit high density optical coatings that are superior to other coating methods, such as Electron Beam Evaporation, R.F. and D.C. Magnetron Sputtering, Ion Beam Assisted Deposition and Reactive Sputtering. All of these produce deposition energies <1eV, whereas cathodic arc plasmas are characterized by relatively high ion energies (20-150 eV), which lead to excellent adhesion and to denser films and therefore better optical characteristics due to the lack of voids in the coating. In addition, our innovative coating technique produces a very low average heat transfer that does not damage even sensitive substrates during the coating process. The Phase I effort will theoretically determine the structure of the required coatings and produce sample coatings of eight stacks of metal oxides by filtered cathodic arc plasma deposition on several substrates. During Phase II, full-scale, large area prototype coatings will be fabricated and tested to ensure reliability and functionality.The proposed new coatings will find commercial applications in diverse arenas, such as space based sensors, automotive and aircraft windows, Wavelength Division Multiplexers (WDM), energy efficient residential and commercial windows and solar cell array surfaces for space applications.

NANOSONIC, INC. P.O. Box 618 Christiansburg, VA 24068
Phone: PI: Topic#:	(540) 953-1785 Dr. Kristie L. Cooper AF 01-058 Awarded: 02MAY01
Title:	Self-Assembled Molecular Coatings for Helmet Mounted Display Visors
Abstract:	This Phase I SBIR program will investigate the feasibility of using molecular self-assembly processes for the formation of spectral coatings on helmet mounted display visors. Electrostatic self-assembly (ESA) involves the simple and low-cost coating of solid substrates by the alternate adsorption of anionic and cationic complexes of polymers, metallic nanoclusters and other molecules from water-based solutions at room temperature and pressure. Each adsorption step adds a single uniform molecular monolayer to the thickness of the total coating. By selecting the molecules incorporated into each of many successive monolayers, the index of refraction may be varied as a function of thickness through the coating, and spectral filter stacks may be formed. Advantages over conventional deposition processes include ability to form uniformly-thick coatings on arbitrarily-shaped substrates of virtually any size, and avoidance of high temperature processing which often either limits substrate choice or leads to unacceptable long-term mechanical performance for polymer-based substrates. During Phase I, NanoSonic will design and fabricate narrowband spectral filters on curved polycarbonate substrates, and evaluate spectral and mechanical properties of the coated test articles. During Phase II, the filter fabrication process will be optimized to allow the low-cost batch coating of visors by an automated robotic coating system.Improved methods for the fabrication of spectral control coatings have defense applications in laser weapon protection, canopy and window coatings and stealth systems, and commercial applications for bulk optical components, microphotonic and optoelectronic device endfaces, and AR coatings for spectacle lenses and windows.

NTI, INC. 4130 Linden Ave., Suite 235 Dayton, OH 45432
Phone: PI: Topic#:	(937) 429-1333 Mr. Robert Shaw AF 01-059 Awarded: 10MAY01
Title:	Helmet-Mounted Display (HMD) Interface Design for Head-Up Display (HUD) Replacement: Exploratory Development
Abstract:	Increasingly, helmet-mounted displays (HMDs) are replacing "head-down" and Head-Up Displays (HUDs) in advanced cockpit interface designs. HMDs offer potential advantages by providing pilots with more direct access to critical visual information, while offering greater flexibility of head movements, less weight, and less consumption of cockpit space. Much of the symbology, functionality and mechanization used in current HMDs can be traced directly to HUDs. But, because HMDs are decoupled from the longitudinal axis of the aircraft, different kinds of information can be presented on HMDs. Thus, questions arise concerning the best manner in which to present the additional information, and its interaction with the traditional HUD information. The purposes of this effort are to define the human performance requirements for both HUD and HMD interfaces as utilized in military missions, and to produce a preliminary HMD design for a no-HUD aircraft. To establish the functional specifications for the interface design, a user-centered design approach employing cognitive work analysis will be used. The results of the analysis will be verified through a simple simulation in which subjects will be presented with the symbology and mechanization concepts envisioned for the preliminary design. Based on these results, a final preliminary design will be generated. The potential applications of the technology that will be designed in this effort are enormous. There is a growing need to provide information to pilots through head-up display technology in both commercial and general aviation cockpits. HMDs could satisfy this need with less expense and less use of valuable cockpit real estate than traditional HUDs. This effort will provide the human performance requirements and design specifications for replacing cockpit HUDs with HMDs. Upon completion of Phase II, an actual design prototype that has been tested and evaluated will exist for demonstrating HMD interface concepts. These products are marketable to airframe manufacturers and airlines as either specifications for hardware design or as a benchmark for evaluating competing HMD technology.

SDS INTERNATIONAL, INC. One Crystal Park, 2011 Crystal Drive, Suite 100 Arlington, VA 22202
Phone: PI: Topic#:	(407) 282-4432 Dr. Dutch Guckenberger AF 01-059 Awarded: 22JUN01
Title:	Helmet-Mounted Display (HMD) Interface Design for Head-Up Display (HUD) Replacement
Abstract:	The ArchAngel HMD-HUD Assessment and Testbed is focused on exploring the feasibility of different concept-designs and symbology for HMD Interface Design for HUD Replacements by combining Subjective & Quantitative Analysis and Modeling & Simulation with Realistic, Distributed Mission Training-Type Test Scenarios & Evaluation models and processes. It's this comprehensive approach to nominating, assessing, selecting, and actually performing simulation-based testing of potential HMD-HUD candidates that sets the ArchAngel Assessment and Testbed Approach apart from other, less comprehensive, approaches. As such, the ArchAngel approach will result in product-sets that include: actual HMD-HUD end-technologies, and a Testbed capable of supporting simulation-based acquisition-processes for HMD-HUD candidates including integration with other aviation-related weapons and weapons systems. SDS will be apply its extensive work to date developing PC-based simulation-Testbeds to assist in selecting high-potential HMD-HUD candidates and performing simulation-based testing of those candidates early in Phase I. The ArchAngel HMD-HUD Testbed will leverage-off SDS Testbed components built for UAVs/UCAVs/Space Maneuver Vehicles/Manned Aircraft to investigate HMD-HUD symbology and techniques for transmitting information from the battlespace to the pilot. The Testbed also includes sophisticated GOTS Computer-Generated-Forces providing a realistic, simulated-combat environment, and selective component-fidelity needed to record parameters associated with determining HMD-HUD effectiveness verses current and projected HUDs. The ArchAngel HMD-HUD Assessment and Testbed Phase I is envisioned to result in multiple HMD-HUD feasibility concepts that will evolve into one or more prototype demonstrations during both Phase I & Phase II, and a Testbed capable of supporting simulation-based acquisition-processes for HMD-HUD candidates including integration with other aviation-related information systems, weapons and weapons systems. Anticipated Benefits of replacing the aircraft's fixed HUD hardware with an ArchAngel HMD-based virtual HUD capability include, but are not limited to: . 360 Augmented Reality Viewer---Enhanced Situational Awareness for Safety and Combat by providing a 360 degree virtual symbology (for example, designator boxes can even show the position of aircraft underneath ownship; and horizon line, overlay terrain, and altitude cues can aid the pilot in orientation). From a pilot performance standpoint, the use of the HMD as the sole transparent display media has the potential to provide a pilot/vehicle interface that is flexible, intuitive, and more capable compared to current technology. These benefits go toward the enhancement of Air Force (and other services) mission effectiveness and aircrew survivability. . BatteSpace InfoSphere Enhancement--AWACS / JSTARS and other friendly sensor and information sources can be displayed with common symbology. For example, an AWACS controller can designate a bandit as bandit #9 and the ArchAngel HMD-HUD would place a #9 next to the designator box displayed, this would allow US warfighters to communicate sorting of targets more efficiently. Lead could tell his wingman to shoot #9 without any confusion. Other examples are "HighWay in the Sky" and Threat-Domes . Weapon Employment Enhancements---New Off-Bore Sight Weapons like Aim9-X can be incorporated into HMD-HUD symbology and operation. . Increased Efficiency and Safety for existing HUD aircraft---HMD-HUD will save significant aircraft weight while simultaneously freeing up valuable display real estate in the cockpit; Removal or the reduction in size of the current HUD combiner may afford the installation of a windscreen that is both stealthy and bird strike safe. . Eye-Protection from Nuclear Flash and Laser Weapons---All forms of obscured OTW vision may benefit with the ArchAngel Safety features of being able to draw the entire virtual world superimposed over the real-world for adverse weather and night. . Increased Efficiency and Safety for existing no-HUD aircraft---An ArchAngel HMD-HUD Kit will allow both military and private sector pilots to benefit. . Increased Efficiency and Safety for existing no-HUD vehicles---Ships, Subs and Armored Vehicles may also benefit from ArchAngel HMD-HUDs.

CHROMALUX, INC. 4665 Albany Street Cocoa, FL 32927
Phone: PI: Topic#:	(321) 637-3780 Mr. Roger J. Molitor AF 01-060 Awarded: 13APR01
Title:	High-Resolution Visual System Development
Abstract:	Chromalux is developing a video projection system that will display 5000 elements of resolution per picture width and 18 million elements of resolution per frame. The purpose of this proposal is to test and evaluate the innovative use of offset electron beams to write and erase images on a liquid crystal light-modulating device, in a ultra high resolution video projection system. Because we have NO PIXELS, the image will not have distracting digital artifacts. Since we do not utilize a fixed matrix array to produce the image, we can very easily geometrically shape the image without lose of light or resolution, and we can produce the geometrically shaped image with little or no distortion. We have an engineering proof of concept system operating today. If the results of our study and test effort are successful, we will be able to provide the Air Force and other simulation dependent entities with an ultra high resolution video projector that can project full color, full motion video images with no smear. This projection system will be the first projection system to fully utilize the capabilities of today's ultra high resolution image generation capabilities.We can take the "FILM" out of movie films. The movie industry is looking for a projector that can produce a full color full motion digital image that is equivalent to or better than film. By our calculations, it will take 3300 lines of resolution to equal the resolution of film based on the fact that film has 80 line pairs per millimeter. This projection technology is capable of producing in excess of 3300 lines of digital video resolution. We anticipate capturing at least 30% of the $10 Billion emerging digital cinema market.

PHYSICAL OPTICS CORP. Electro-Optic & Holography Div, 20600 Gramercy Pla Torrance, CA 90501
Phone: PI: Topic#:	(310) 320-3088 Dr. Tin M. Aye AF 01-060 Awarded: 26APR01
Title:	Laser-Illuminated Sub-Image Scanning High Resolution Light Engine
Abstract:	Physical Optics Corporation (POC) proposes to address the poor resolution and limited field-of-view of current head-mounted-display (HMD) light engines, which are based on miniature CRTs, LCDs, microdisplays, and laser scanned displays. POC proposes a full color high resolution HMD light engine based on laser illumination, a high speed CMOS-LCD spatial light modulator (SLM), with either line image scanning or frame scanning. The proposed approach offers superior resolution (5k x 4k pixels) from a relatively low resolution CMOS-LCD SLM, taking advantage of its high refresh speed and relatively slow line image or subframe scanning. The proposed technology is made commercially attractive by its unique integration of currently available commercial components and low cost fabrication techniques. The proposed effort will focus on developing a compact Laser-Illuminated Sub-Image Scanning (LASIS) light engine demonstration unit in which COTS components such as RGB laser diodes and CMOS-LCD microdisplays will be integrated with POC's liquid crystal digital scanners to generate color sequential full resolution images for current U.S. Air Force simulator HMDs. In Phase I, POC will demonstrate the feasibility of the proposed approach through design, analysis, and an experimental proof-of-concept demonstration, so that in Phase II we can build a preproduction prototype light engine.The proposed compact, lightweight, high resolution HMD light engine will advance head mounted display technology. Applications include virtual environment training, avionics, medicine, education, CAD/CAM, video conferencing, entertainment, and video games.

PROTOBOX LLC 1464 North Broad St. Fairborn, OH 45324
Phone: PI: Topic#:	(937) 879-2588 Mr. Ronald Ewart AF 01-061 Awarded: 10MAY01
Title:	Real-time Embedded Simulation Performance Monitoring and Analysis for Distributed Mission Training (DMT)
Abstract:	Protobox LLC proposes to develop an innovative network simulation performance monitoring system that will enable researchers to understand and quantify the performance of the simulation while it is being conducted. The system is called the "Embedded Simulator Test Evaluation Monitor" (ESTEEM). ESTEEM will measure simulation latencies and accuracies, identify and pinpoint sources of problems, provide status and entity information, and immediately display information to the researcher. ESTEEM is based upon a modular multi-level concept. Simple low-cost agents will be developed to gather basic information about the simulation at each network node. Critical simulation nodes can be augmented with additional ESTEEM modules including a GPS capability, hardware simulator performance measurement capability, and a researcher control and display. The multi-level concept is not a "shell" that would incur additional layers of overhead as the capability expands. Rather, it is modular building block approach that adds additional processing capability with each additional module. As the system is expanded, its accuracy and capability is increased. Two innovative techniques allow data to be gathered and returned to the researcher without impacting the simulation or network performance. ESTEEM will enable researchers to conduct experiments evaluating the interactive performance of network simulations, human pilots, and simulation participants. ESTEEM will be powerful tool supporting the improvement of network simulation and of Distributed Mission Training (DMT). The proposed system will be the first system to ever provide researchers with quantitative information about the performance of a network simulation while the simulation is being conducted. Engineers can use ESTEEM during the development of a simulation to optimize the interactive performance of the simulators located at various network nodes. ESTEEM can quantify the simulation latencies from stick input at one site until a pilot perceives the result of that input in a simulated aircraft at another site. Latency contributions can be broken down into components so that problem areas can be identified and minimized. The researcher can use ESTEEM to study the interaction between the network simulation and human participants. Installation of ESTEEM systems, located throughout a DMT environment, will permit researchers to certify the quality of the simulation when it is initially developed, and verify proper operation on a day-to-day basis. It is critical to use the embedded simulator performance measurement tool to measure the simulator performance while a simulation is being conducted. Results obtained from a network simulation experiment or distributed training exercise can only be trusted if the simulator performance has been verified.

SYSTRAN FEDERAL CORP. 4027 Colonel Glenn Highway, Su Dayton, OH 45431
Phone: PI: Topic#:	(937) 429-9008 Mr. George J. Valentino AF 01-061 Awarded: 07MAY01
Title:	SNAPpy 2001 - DMT Performance Modeling and Analysis System
Abstract:	Systran Federal Corporation (SFC) and Science Applications International Corp. (SAIC) propose to design, develop, demonstrate, and commercialize the SNAPpy 2001T DMT (Distributed Mission Training) Performance Monitoring and Analysis System. In Phase I, we will use our past experience and residual hardware and software from the 1998 "SNAPpy low-latency network interface and real-time data collection system" and the 1998 "AgentsTools intelligent software agents toolkit to support distributed simulations" programs to formulate a refined concept for a real-time performance monitoring and analysis "system." Our focus will be on utilizing open-systems and standards-based software to develop SNAPpy 2001 as a software product that would operate on heterogeneous distributed simulation platforms. SNAPpy 2001 will include the functions and features of both a real-time data logger (SNAPLoggerT) and a quasi-real-time data monitor and analysis system (SNAPViewerT). Both SNAPLogger and SNAPViewer will be flexible, allowing the simulation developer to tailor the specific data collection, viewing and analysis functions required for his requirements. The SNAPLogger will log entity state data from both computer-generated entities and from real people-or hardware-in-the-loop. The overall SNAPpy 2001 "system" will have application to developers and users of distributed simulations, whether they are HLA-based or non-HLA (legacy) simulations. Demonstrations will be provided.Our solution provides for (1) the unobtrusive, real-time, time-tagged collection of data from both real people-and hardware-in-the-loop systems and of data from purely computer-generated entities, (via the SNAPLogger) and (2) the movement of this data in near-real-time to a monitoring and performance analysis node for the presentation and analysis of the data (the SNAPViewer). Our solution is primarily software-based, with the main platform being a COTS Windows 2000 platform and standards-based data acquisition modules. Time stamps can be via GPS, IRIG-B, or other methods. We employ proven SFC and SAIC developed methods to minimize the latency between when data is sensed and the time-tag associated with this data, thus providing accurate insights into the simulation by the user. Intelligent software agent technology is used for efficiency, fault-tolerance, convenience, and customization.

AEGIS RESEARCH CORP. 7799 Leesburg Pike, Suite 1100 North Falls Church, VA 22043
Phone: PI: Topic#:	(412) 471-3456 Bill Elm AF 01-062 Awarded: 09MAY01
Title:	Distributed Crew Interface for Autonomous Satellite Operations
Abstract:	A shift in the concept of operations of military satellite operations centers toward "lights out" autonomous intelligent agents for normal operations and dynamically configured `on-call' crews with a variety of physical interface devices during emergencies requires a breakthrough in decision-centered distributed information systems. In these types of domains, the critical needs focus on understanding and providing for the information needs of the operators, supporting the collaboration needs of the environment, and providing effective decision support in order to transform the environment from an inefficient, data-intense, high cognitive demand situation to an efficient, information-rich, high-performance human-machine system. The key innovation here will be the design of support tools for a variety of user interface technologies and thus a variety of physical sizes, visual characteristics, and interaction mechanisms. This will be accomplished by an explicit and variable mapping of the decision and information requirements using a Function Based Cognitive Work Analysis (adapted from Woods, Rasmussen, Vicente, et al) to the `coverage' of particular user interface components. Our proposed effort will both develop the innovative decision support features for the next generation SOC as well as extend the CSE methodology in two key areas: to address "dynamic workspace variety" and "dynamic crew composition".The results of this work will be an extremely effective approach to capture the essential elements of this dynamic crew structure concept. First of all, the underlying functional analysis is extremely useful for identifying critical demands of the work domain (and thus critical functional areas for multiple operator support). This is essential for defining needed decision support. Second, regions of responsibility within the functional framework and decision map - for a variety of contingency operations - can be defined. This will be valuable for defining adaptive roles and responsibilities for the varying tempos of operation toward generating a clearly defined `transition plan' as a cognitive hypothesis in terms of collaboration and design requirements for the shift from normal to contingency operations. As "on demand expertise" becomes more commonplace in an internetworked enterprise, the marketplace need for these types of Decision Support Systems will continue to skyrocket. The associated services industry is expected to grow at a commensurate rate, focusing more and more on Decision Centered solutions as a greater share of that service area (e.g. the rapid success of companies like The Nielsen Norman Group).

APTIMA, INC. 12 Gill Street, Suite 1400 Woburn, MA 01801
Phone: PI: Topic#:	(781) 935-3966 Dr. Elliot E. Entin AF 01-062 Awarded: 26APR01
Title:	Distributed Crew Interface for Autonomous Satellite Operations
Abstract:	In this Phase I SBIR, the Aptima team will draw upon its experience and expertise in studying, designing, and supporting effective distributed teams, and its long-term expertise in the design of human-centered interfaces for military command and control teams to design the interface for a remote distributed satellite maintenance crew. The Phase I work will result in the requirements for a human-centered interface that allows distributed crew members to communicate, maintain situation awareness, and collaborate in a wireless environment using advanced information technology tools to detect, diagnose, and issue commands to resolve satellite anomalies and emergencies. The Phase I effort will also produce the design for a simulation environment and experiment plan to empirically evaluate the interface. In Phase II an advanced prototype interface will be developed, along with the simulation environment that will be used to test the interface. The prototype will be evaluated using the experiment design developed in the Phase I effort. The methodology and approaches that are developed in Phase II can be adapted and applied in other domains in which distributed teams are involved in diagnosis and resolution of unanticipated disruptions that occur in complex automated systems.The concepts, designs, and findings that emerge from this SBIR effort will have direct application in DoD agencies, non-DoD government agencies, and corporate firms in which distributed and possibly ad hoc teams of experts are called upon to collaborate in a distributed environment to detect, diagnose, and stabilize anomalous or emergency conditions that occur in a remotely located automated systems. Potential application domains include law enforcement, remote medical interventions, and communications systems.

CYBERNET SYSTEMS CORP. 727 Airport Boulevard Ann Arbor, MI 48108
Phone: PI: Topic#:	(734) 668-2567 Dr. Charles J. Jacobus AF 01-062 Awarded: 23APR01
Title:	Distributed Crew Interface
Abstract:	The US Air Force requires the capability to control, upload and download management information in order to coordinate crew interactions, even when the crew is remotely located. Because of limitations in communication infrastructure and shared databases, it is difficult for collaborating engineers, planners, analysts, and military commanders to allocate these assets in a timely manner. This process also requires the use of systems like the MILSATCOM ACMS that does not provide sufficient coordination support for large commercial satellite operators. A system more aligned with commercial practices such as WWW, CGI, and JAVA usage will offer the DoD further leverage as it upgrades its systems. A new generation of collaboration tools must be developed that, while implemented in CGI and JAVA and distributing data as HTML, must mimic the useful attributes of existing tools. Cybernet intends to provide this system by developing a capability that will allow Air Force personnel to make simple requests for information using the World Wide Web, e-mail, FTP and other data via a JTA compliant interface. This design will also provide an ISA the capability for the remote administration of collaboration and database upload and download into Air Force installed common support stations.The system proposed in this effort would be used to enhance Cybernet's current network products. This market is composed of sophisticated individuals and small to medium sized business or workgroups in larger business or the U.S. Government. This group requires the flexibility that larger organizations achieve through extensive support teams, but do not have the resources to get it at the present time.

MOBILEFOUNDATIONS, LLC 6607 Mayfair Drive, #302 Falls Church, VA 22042
Phone: PI: Topic#:	(703) 862-9343 Mr. Jeffrey Fox AF 01-062 Awarded: 14MAY01
Title:	An Automated Tool to Enable the Distributed Operations of Air Force Satellites
Abstract:	Air Force satellite program officers are being driven to explore greater levels of computerization due to budgetary reductions, evolving ground system and range architectures, and the increased number and complexity of missions. mobileFOUNDATIONS will demonstrate that advanced automation can meet these challenges. Today, mobileFOUNDATIONS's innovative Spacecraft Emergency Response System (SERS) enables autonomous and distributed operations at NASA, saving millions of dollars/year. Upon detecting anomalies, SERS dynamically builds response teams based on the problem's type and severity and on the crew's skills, availability, and communications devices. SERS then enables distributed team collaboration via wireless devices. However, the Air Force needs an even more capable system, so mobileFOUNDATIONS proposes a user-centered Phase I program to: (1) understand Air Force user (human effectiveness) and architectural requirements; (2) study the impacts of current high-risk technology issues, like security; (3) demonstrate a proof-of-concept functional prototype; and (4) identify essential capabilities needed for Phase II operational prototyping.The successful conclusion of this SBIR program will result in more efficient and effective Air Force satellite program ready to better handle future challenges. mobileFOUNDATIONS will utilize this SBIR's technology in the development of a generic automated response system that will improve the efficiency of enterprises that depend on team-based distributed activities.

CONCEPTUAL MINDWORKS, INC. 4318 Woodcock Drive Suite 210 San Antonio, TX 78228
Phone: PI: Topic#:	(210) 536-1388 Dr. Mark Sloan AF 01-063 Awarded: 09MAY01
Title:	Surface Decontamination Using Electromagnetic Field/Laser Emitters
Abstract:	The proposed project will develop the scientific basis for a sensing and decontamination system capable of detecting and destroying chemical and biological warfare agents (CBWAs). The system would incorporate sensors that could be contained in units which would passively interact with the environment. Alternatively, the sensors could be sprayed on surfaces of sensitive equipment, clothing and even skin without damaging the surfaces. The sprayed version of these sensors would be colorless or subdued in color until examined with an activator light source. After the photo-activation of the sensor redox reaction, either an electromagnetic field (EMF) and/or a laser would be used to destroy the CBWA. The proposed concept uses DNA aptamers for CBWA recognition, diazoluminomelanin (DALM) as the free radical label and DNA substrate, electron spin resonance (ESR) for signal detection, advanced signal processing for optimal pattern recognition and rejection, and either microwave or laser irradiation for destruction. The DNA grid is based on the SELEX process that allows binding of known and unknown CBWAs (e.g., genetic recombinant), the latter by binding to components that are common to known CBWAs. A spin-off project is that the tightly bound DNA aptamer sequences could be eluted, amplified, and purified for the production of neutralizing agents. Phases I - III would be conducted within a partnership including Conceptual MindWorks, Inc., Pacific Northwest National Laboratory, Battelle Memorial Institute, McKesson HBOC Clinical and Biological Services, Litton TASC, and Honeywell Corporation. Fast detection and destruction of CBWAs would save lives by providing time to adopt protective measures. Commercially, medical personnel would use biosensors to rapidly detect and destroy viral, fungal, and bacterial organisms infecting open wounds, such as severe burns, without producing further trauma. Immediate decontamination of wounds would reduce complications from surgery resulting from secondary infection. Industrial hygienists would use biosensors to limit exposure to harmful organisms, such as biological toxins in food preparation areas (e.g., E. coli O157:H7).

CREARE, INC. P.O. Box 71 Hanover, NH 03755
Phone: PI: Topic#:	(603) 643-3800 Dr. Michael D. Jaeger AF 01-063 Awarded: 25APR01
Title:	Low Temperature Plasma Source for Chemical and Biological Decontamination
Abstract:	The excited or dissociated gaseous species created in non-thermal glow discharge plasmas are effective agents for killing or neutralizing certain biological or chemical warfare agents. For decontaminating sensitive equipment or personnel, the effluent from such plasmas must be near room temperature to prevent unintentional dispersal of the hazardous warfare agents and to avoid harming the equipment or persons being cleaned. We propose a unique method for generating room temperature decontaminating/sterilizing plasma effluent without the use of bottled gases. The technique can be embodied in an easily fieldable system that employs a handheld or fixed-position Cool Air-Plasma Gun. In Phase I, we will demonstrate the fundamental concepts necessary for generating cool decontaminating plasma effluent without using bottled gases. In Phase II, we will build a prototype Cool Air-Plasma Gun system and demonstrate its efficacy for decontaminating or sterilizing simulants of chemical warfare agents.Creare's cool plasma effluent technology is expected to provide a deployable system for decontaminating sensitive equipment or even personnel. Such a system will provide significant benefits to defense against chemical or biological warfare or terrorist acts, clean-up of toxic industrial chemicals, and sterilization of medical equipment and devices.

FEPET, INC. 3006 Longhorn Blvd., Suite 107 Austin, TX 78758
Phone: PI: Topic#:	(512) 339-5020 Mr. Leif Thuesen AF 01-063 Awarded: 25APR01
Title:	CBWA Decontamination Unit Based on Carbon Nanotube Cathodes
Abstract:	It is proposed to use a carbon cold cathode as a source for an electron spray Chemical and Biological Warfare Agent (CBWA) decontamination unit. The goal is to design a device using the cold cathode source and model all of the necessary parameters of its operation. Electron beam technology has been shown to be an excellent tool in medical treatment and environmental decontamination systems. Phase I of this program will be a study of the parameters needed for an electron spray device to destroy CBWAs, limits so that materials and people are not injured through its use, modeling of the device to obtain specifications for operation and the applicability of a cold cathode to such a device. Construction and testing of a prototype device will be the objective of Phase II. In Phase III, the device will be advanced to commercialization. The applications of such a device will not be limited to military use in CBWA decontamination. Controlled destruction of CBWAs would also be possible. It could be used in industry to assist in cases of chemical spill clean up or factory emission control.

PHYSICAL OPTICS CORP. 20600 Gramercy Place, Building 100 Torrance, CA 90501
Phone: PI: Topic#:	(310) 320-3088 Dr. Gregory Zeltser AF 01-063 Awarded: 26APR01
Title:	Photocatalytic Plasma Jet
Abstract:	Physical Optics Corporation (POC) proposes to design and develop a novel photocatalytic plasma jet to address the needs of the Air Force (and the other services) to destroy chemical and biological warfare agents on surfaces ranging from human skin to concrete and soil using electromagnetic field emitters. The proposed Photocatalytic Plasma Jet (PPJ) will generate a non-thermal, ambient-pressure plasma discharge of a high velocity water-borne effluent stream of highly reactive chemical species. The novel key concept is preionization of the water by semiconductor-aided photocatalysis to decrease dielectric barriers to the ignition of the corona discharge. The PPJ design is grounded on patented POC technologies developed for fabrication of plasma diagnostics, light guiding systems, and sol-gel coating, and will be more power- and cost-efficient than current experimental devices. In Phase I, POC will develop a PPJ benchtop prototype for laboratory proof-of-concept demonstration and analysis of its performance at a DOD facility. In Phase II POC will produce a portable prototype device to demonstrate destruction of the CBWAs in in vitro experiments. These will be followed by additional evaluations of exposure parameters to prevent damage to skin and mucous membranes.The successful completion of this project will result in a reliable, mobile, and cost-efficient device and novel technology for non-thermal plasma decontamination of biological and chemical warfare agents on surfaces, including skin, also suitable for a wide range of commercial applications, notably hospital infection control, sterilization, and decontamination of instruments and clothes.

SOLUS BIODEFENSE 700 New Hampshire Ave NW, # 1008 Washington, DC 20037
Phone: PI: Topic#:	(202) 333-3175 Dr. Roger von Hanwehr AF 01-063 Awarded: 17MAY01
Title:	Surface Decontamination Using Electromagnetic Field/Laser Emitters
Abstract:	SOLUS BIODEFENSE proposes a novel rf-excitable, molecularly-targeted BWA defeat technology, consisting of a microwave (MW)-excitable, UV-fluorophore modified, bioluminescent polymer and a series virabiocides designed to provide multimechanism synergistic agent kill and avid agent targeting directed at biomolecular surface matrices of spores, enveloped viruses, live microbial agents, and biotoxins. The virabiocides will consist of energy-activatable chromophores modified with charge specific agent targeting moieties, and with moieties likely to undergoe exothermic decomposition within bioagent macromolecular matrices. Mechanisms of kill integral to this design include: 1) sonoluminescent plasma effects induced by pulse microwave excitation of the polymer, 2) UV flash emission, 3) energy transduction-activated chromophore biolethality, and 4) focal exothermic energy release from decomposition events in proximity to molecular target sites within spore walls and viral envelopes. Both free and polymer-coupled virabiocides (the latter for the purpose of attaching CW nerve agent hydrolyzing enzymes to the system in Phase II) will be developed as integral molecular technology components. The agent defeat effectiveness of this technology will be extensively tested in experimental settings of high peak energy/rapid rise-time pulsed MW irradiation at multiple frequency bandwidths. Effectiveness of surface decontamination will be evaluated using anthrax spores, gram negative bacilli, enveloped influenza virus simulants, and biotoxins.The proposed microwave-excitable molecular-enhancement agent defeat technology is expected to address a broad range of markets in the biomedical, agriculture, veterinary, food science, materials industry, and environmental decontamination areas. Furthermore, advances in the technology of using charge groups to design new agent targeting molecules with fluorescent tagging properties opens huge commercial market potential internationally in the biotechnology and clinical domains. Furthermore, the development of molecular directed energy targeting and defeat enhancement technologies has significant future potential for the treatment of infectious disease as regards open contaminated wounds, and for the non-invasive molecular illumination-guided treatment of cancer.

BTMD, INC. 11401 Mountain View Rd., Suite 201 Damascus, MD 20872
Phone: PI: Topic#:	(301) 253-0540 Mr. Frank S. Wodoslawsky AF 01-064 Awarded: 07MAY01
Title:	Simulated Panoramic Night Vision Goggle Helmet-Mounted Display for Simulated NVG Imagery
Abstract:	The Simulated PNVG project will develop a proof of concept helmet mounted display system that will simulate the current Panoramic Night Vision Goggle (PNVG) system. The prototype system will preserve the form, fit and function associated with the current PNVG using available display technology. The selected display technology for the simulated PNVG will integrate into the PNVG so as to preserve the form and fit as much as feasible. The display system will also need to support a variety of programmable video formats for the computer generated imagery in an effort to support research objectives associated with the physics based visual simulation of night vision goggle imagery.With the ever demanding mission requirements placed on our pilots for effective and safe night time operations, the significance of an accurate night vision goggle training platform can not be over stated. Mission preparation and the ability to rehearse various mission profiles provides a valuable tactical edge for our US military forces. The proposed Simulated PNVG system will provide an accurate and cost effective training aid. In addition, the technical advances produced from this development effort will be integrated into our current commercial set of high performance HMD systems.

INSIGHT TECHNOLOGY, INC. 3 Technology Drive Londonderry, NH 03053
Phone: PI: Topic#:	(603) 626-4800 Mr. Eric Littleton AF 01-064 Awarded: 25APR01
Title:	Simulated Panoramic Night Vision Goggle Helmet-Mounted Display for Simulated NVG Imagery
Abstract:	Insight Technology, Inc proposes to design and deliver a proof-of-concept demonstrator of a helmet-mounted display system to support ground-based training for the Integrated Panoramic Night Vision Goggle (I-PNVG). The demonstrator will integrate with the physics-based visual simulation system (Night Vision Training System) of Image Intensification (I2) based night vision goggle imagery currently in development. The principle problem to be addressed is how to configure a head-mounted display that provides the increased field of view and approximate image characteristics (resolution, color, decay rates, etc.) of I-PNVG while at the same time providing the weight, center of gravity, and form, fit, and function characteristics of I-PNVG. Existing miniature CRT and flat-panel displays will be analyzed to determine which technology offers the best balance between image quality characteristics (resolution being top priority) and minimizing weight and center of gravity deviations from the actual goggle. The I-PNVG monocular will be modified to accept the selected display. Eyepiece optics will be designed to accommodate the display while providing a panoramic image consistent with that of I-PNVG. The modified monocular assemblies will be mounted to the actual I-PNVG pilot adjustment shelf to maintain commonality with form, fit, and function of the actual system.The development of a simulation-based helmet-mounted display that closely matches the form, fit, and function characteristics of the Integrated Panoramic Night Vision Goggle system will provide for realistic training in the safe and relatively low-cost simulation environment. The simulation system also will permit development of modified tactics, techniques, and procedures for a wide field of view night vision goggle in the ground-based simulation environment. Additional benefits will include the capability to develop and evaluate future I-PNVG enhancements in a simulation environment prior to in-flight use and evaluation of pilot performance improvements brought about by the wide field of view goggle.

SPEECH TECHNOLOGIES CORP. 2414 NE Java Way Hillsboro, OR 97124
Phone: PI: Topic#:	(503) 648-9822 Dr. Brian Womack AF 01-065 Awarded: 10MAY01
Title:	Advanced Speech Production Models
Abstract:	Current speech processing systems address the effects of channel noise and assume that all speakers are always in the same stress state. Neutral speech occurs when the speaker has no task obligation other than to speak. Perceptually or physiologically induced speaker stress occurs in non-neutral conditions such as G-force, vibration, environmental noise, or emotion. Depending upon the type and degree of perceptual or physiological stress, the glottal source, vocal tract frequency structure, fundamental frequency, and intensity or duration are all affected in different ways. In addition, for a given speech utterance, a speaker's production can shift from one type of stress state to another dynamically. There are two main approaches to addressing the problem of speaker induced stress: (i) stress robust speech production models and (ii) stress robust speech processing algorithms. This study will focus on the first approach. By understanding the effects of speaker induced stress, it is possible to create models that are less sensitive to stress induced variability. These new features will then be applied as an example to the stressed speech recognition problem to determine if they result in improved performance.Current speech processing algorithms work best with neutral speech produced in quiet environments. In many settings, speech can be produced in environments that cause perceptual speaker stress such as emotion, task workload, or perceived background noise. During perceptual stress, the speaker will modify their production of speech to assist the listener's ability to receive the intent of the speech or to simply express emotion. Alternately, the human body can be exposed to physiological stress induced by vibration, acceleration, deceleration, or changes in the makeup of the air supply. Both of these types of stress create a significant change on the speech signal before it leaves the vocal tract. With better speech production models that seek to minimize the variability introduced by stress and noise, a wide range of speech processing applications will benefit. This is a foundational piece of technology that is required to take speech processing to the next stage in performance and reliability. Commercial applications will benefit from more robust speech recognition, for example, because speakers will be able to express emotion naturally in the real world environments that are part of their every day experience. This is an often quoted complaint with current speech recognition systems currently available commercially.

BEAM TECH CORP. P.O. BOX 680486 San Antonio, TX 78268
Phone: PI: Topic#:	(210) 567-2989 Mr. Charles A. Hubbard AF 01-066 Awarded: 09MAY01
Title:	Electromagnetic Field Overexposure Indicator
Abstract:	There is a need for a personal radiofrequency radiation (RF) alarm that has the ability to detect high levels of electromagnetic field exposures, in both near and far-field situations, so that personnel can perform their duties without health hazards in environments mandated by DOD operations. This project will evaluate the feasibility of developing a small, inexpensive portable alarm to detect exosures to RF electric and magnetic fields, up to extremely high intensities; at the latter, electronic devices could be inactivated. The approach is to use a passive device, based on the biosynthesized polymer diazoluminomelanin (DALM) suspended in an agar gel, for detecting, indicating with an alarm, and recording the exposure. The system would have a redundant active electronic component, which would provide alternative audible and visual alarm features. The DALM and the DALM-gel technologies were invented or developed by Air Force Scientists; Beam Tech Corporation (BTC) has exclusive license to the biological and chemical synthesis of DALM. In addition to this DALM-agar bubble and luminescence technology, BTC will identify and consider as alternatives both commercially available and patented technologies that could serve the same purpose, or could serve as components of the technology to be designed.The personal RF Overexposure Indicator to be designed and evaluated for feasibility will be unique in that it will not be at risk for inactivation by the very electro- magnetic exposures for which it is supposed to provide an alarm. It has the additional potential benefit of recording the intensity of the exposure, for determining the extent of exposure over a period of time between examinations. By including a comprehensive of any currently commercially available or otherwise patented technology, Beam Tech Corporation could identify devices or components that will assist in the development of an active electronic component, to be included as a redundancy feature in the Overexposure Indicator. While the market for the device would be extensive within the DOD, it would also be useful to U.S. Government Security Agencies. It might also be useful for persons who work in the private sector in the vicinity of intense RF sources, but who would not knowingly and purposefully allow or expect themselves to be exposed. A complete market evaluation is not possible at this time, with the limited preliminary information available to BTC. This would become possible with the development of prototype information in a Phase II project.

LUNA INNOVATIONS, INC. 2851 Commerce Street Blacksburg, VA 24060
Phone: PI: Topic#:	(540) 953-4273 Mr. Thomas Wavering AF 01-066 Awarded: 25APR01
Title:	Nanomaterials for Low-Cost Electromagnetic Field Alarms
Abstract:	The development of small, lightweight, and low cost electromagnetic overexposure alarms is needed for numerous military and commercial applications involving high intensity electromagnetic fields (EMF). Exposure to high intensity EMF can cause deleterious effects within humans including: altering cell growth rate; decreasing the rate of cellular respiration; altering metabolism of carbohydrates, proteins, and nucleic acids; effecting gene expression and genetic regulation of cell functions; and numerous other degenerative consequences. Current devices to monitor EMF exposure are prohibitively expensive and not suited for field measurements on individuals. For the Phase I program, Luna Innovations proposes to utilize conductive nanomaterials for fabrication of low cost EMF alarms for use by the Department of Defense. Initial work will focus on the development of EMF sensing components utilizing different nanoscale and thin film technologies. Ionic self assembled films and carbon nanostructures will be combined to fabricate nanoscale antennas, loop detectors, and storage devices for quantification of electromagnetic fields. Due to the size and structure of the EMF sensing nanomaterials, the sensors can be tailored to optimize sensitivity, operating frequencies, and performance.The proposed sensor technology has immediate use for measurement of high intensity electromagnetic fields in military, power, and medical applications. The nanotechnology components will have additional application in the development of thin film batteries, photovoltaics, flexible displays, and advanced medical imaging technology. The technology demonstrated during the proposed Phase I program will allow Luna to capture a significant share of the initial target market segment through Luna's proven ability to transfer products from research to market.

US MICROBATTERY, INC. 74 Batterson Park Road Farmington, CT 06032
Phone: PI: Topic#:	(801) 225-1974 Dr. Rodney LaFollette AF 01-066 Awarded: 14MAY01
Title:	Credit-Card Sized, Autonomous, Electromagnetic Field Detector
Abstract:	The battlefield envronment requires accurate and reliable detecton of electromagnetic field detection for militay personnel. This proposal describes the evaluation of electromagnetic detection devices, memory modules and transmitters and then developing the systems (miniaturize them) down to the level of incorporation onto an integated circuit (IC). This work proposal include the adaptation of microscopic batteries fabricated by cleanroom microfabricaton techniques already successfully demonstrated by the company. Microscopic batteries, together with photovoltaic devices, will be controlled byfuzzy logic and will provide the power required to render this devide completely autonomous. If needed, this power spply can be designed to have a multi-voltge capability, both for discharge and charge. This provides the opportunity to optimize performance in both the charge and discharge regimes.Small, autonomouns electromagnetic field detection will help protect personnel in the battlefield environment and a civilian version would help determine if there a high levels of electromagnetic radiation originating from cellular telephones.

CREARE, INC. P.O. Box 71 Hanover, NH 03755
Phone: PI: Topic#:	(603) 643-3800 Mr. David B. Kynor AF 01-067 Awarded: 25APR01
Title:	Disorientation Analysis and Prediction System
Abstract:	Spatial disorientation is a significant problem in military aviation that has resulted in loss of life and aircraft. Creare proposes to develop a Disorientation Analysis and Prediction System that can be used in laboratory research, pilot training, and accident investigation. The system consists of a predictive model, which provides an estimate of the pilot's perceived orientation, and an orientation analyzer, which is an expert system that determines his degree of disorientation. We will also investigate new sensors to provide a quantitative measurement of pilot attentiveness and a new technique for making quantitative assessments of the likelihood of spatial disorientation during flight. This system is intended to serve as the basis for an in-flight monitoring system to be installed in aircraft. In Phase I, we will conduct a review of existing literature, formulate algorithms for quantifying spatial disorientation, investigate the use of additional sensors capable of measuring pilot activity, prepare a system design, and develop a software prototype. The primary private sector application for the technology developed under this program is in civilian aviation. The system developed under this program would be desired by the civilian aviation community to assist with pilot training, provide an in-flight warning of conditions likely to lead to disorientation, and determine whether or not disorientation was a factor in accidents.

NTI, INC. 4130 Linden Ave., Suite 235 Dayton, OH 45432
Phone: PI: Topic#:	(937) 254-3171 Dr. Robert D. O'Donnell AF 01-067 Awarded: 26APR01
Title:	Human Orientation Model for Spatial Disorientation Countermeasures
Abstract:	The goal of this effort is to model human perceptual orientation in a way that it can, as part of the flight control system, alert pilots to various spatial disorientation (SD) conditions. NTI will survey existing models and develop a recommended universal model of how the human perceive motion in the maneuvering environment. The model will then be embedded into an advanced desktop flight simulator (the Flight-Performance Assessment Simulation System -- F-PASS), which simulates the F-16 aircraft with exceptional fidelity. Because F-PASS provides accurate data on the aircraft position and state, it will enable us to generate flight conditions in the simulator, and integrate these with the human model. This will permit simultaneous display of: 1) the position of the aircraft in space, and 2) the human's modeled perception of the aircraft. Pilots will be able to view SD conditions repeatedly, and fly into known SD situations to see the discrepancy between their expected perceptions and actual conditions. PhaseII will propose final development of the system, as well as ultimate installation in the centrifuge, allowing the pilot to actually experience and graphically see the disorientation. Ultimately, the system will provide the basis for installation in actual aircraft.The system to be developed here will serve as a training, research, and operational countermeasure to SD. As such, it has applicability far beyond the obvious fighter aircraft community. SD accounts for nearly 35% of private and commercial aircraft accidents. Therefore, the product will be of considerable interest to the FAA, airlines, light aircraft manufacturers, and to foreign governments.

APTIMA, INC. 12 Gill Street, Suite 1400 Woburn, MA 01801
Phone: PI: Topic#:	(781) 935-3966 Dr. Gavan Lintern AF 01-068 Awarded: 11APR01
Title:	Work-Centered Interface Technology
Abstract:	In complex sociotechnical systems such as military command and control, multiple individuals must work with complex and dynamic information from many diverse sources. Methods are needed to increase worker productivity in such systems by reducing the cognitive complexity of the multi-system interface. We propose a revolutionary approach to interface design for such systems, drawing on the techniques of Cognitive Work Analysis to design a Virtual Information-Action Workspace tailored for a work domain. The workspace will be structured using an abstration hierarchy that captures the terms and relationships natural to workers in the domain. Intelligent agents will support the information location, retrieval, and fusion capabilities needed by the Workspace. Agents will be designed to make the Workspace adaptive, so that users can create the agent capabilities they need to deal with unanticipated situations and new work demands. Intelligent agents will be the means by which workers can "finish the design" of the Workspace to meet their needs. In Phase I we will demonstrate the integration of CWA methods and tools with intelligent-agent-building capabilities to produce a Workspace design for a selected C2 domain. In Phase II we will build the Workspace and evaluate its effectiveness in increasing worker productivity.There is a virtually unlimited market for methods and tools that can increase the productivity of workers interacting with complex systems of systems. Tools for the creation of Virtual Information-Action Workspaces will directly benefit, for example, military C2 centers, air traffic control centers, hospitals, virtual manufacturing environments, managers of corportate databases, and both military and commercial maintenance operations.

CHI SYSTEMS, INC. Gwynedd Office Park, 716 N. Bethlehem Pike, Ste 30 Lower Gwynedd, PA 19002
Phone: PI: Topic#:	(215) 542-1400 Dr. Wayne W. Zachary AF 01-068 Awarded: 11APR01
Title:	Work-Centered Interface Technology
Abstract:	The mismatch between worker needs and information systems design and performance has long been noted, and has given rise to a long body of research on ways to factor the user more explicitly into the interface and system design process. Active interfaces that act as infomediaries between underlying systems and their users, offer the most comprehensive solution to this usability problem, but also pose the greatest technological challenge. The proposed research team at CHI Systems has evolved, through a series of recent applications, a novel work-centered active interface reference architecture, called the Work-centered Infomediary Layer (WIL) architecture. This proposal seeks to create a WIL Application Toolkit (WAT) -- a set of software tools to support and streamline the process of creating WIL interfaces. Phase I develops a WAT concept of operation and architecture, and integrates these via a storyboard prototype . Phase I also defines a detailed development plan for a full-scale Phase II system, assesses the benefits and commercial potential of WAT, and identifies specific candidate Air Force C2 domains on which a full-scale Phase II WAT will be tested and applied.The commercial value of WAT is derived from its use to develop Work-centered Infomediary Layer (WIL) applications to various domains in commercial sector, such as aerospace, network management, call center operations, and medicine. WAT can be commercialized as vehicle for consulting/system integration efforts to develop custom WIL applications, as well as sold directly to development and end-user organizations as an active interface construction tool.

STOTTLER HENKE ASSOC., INC. 1660 So. Amphlett Blvd., Suite 350 San Mateo, CA 94402
Phone: PI: Topic#:	(206) 545-1478 Mr. Terrance L. Goan AF 01-068 Awarded: 18APR01
Title:	Facilitating Work-Centered Interface Development through Patterns
Abstract:	We propose a novel work-centered interface development environment that will dramatically reduce the complexity of interaction design. To this end, we will support an enhanced Contextual Design process with a set of tools that will enable developers to draw on the aggregate experience of other work-centered interface designers. This will be achieved through the collection and application of proven design/interaction patterns that will, among other things, enable developers to resolve the conflicts between agent autonomy and user control requirements. Further, WorkWell will provide an intuitive incremental process for the ontology development and semantic mapping that will be essential to the creation of homogeneous interfaces to the very heterogeneous JBI resources. We will ground our efforts in a domain that we know very well - Defensive Information Warfare (DIW). There is currently a great need for work-centered interfaces that can help network security professionals cope with the great quantity and diversity of data that must be analyzed, as well as incredibly short decision cycles. Our Phase I investigation will result in a detailed work-centered interface development procedure that will form the foundation for the full-scale implementation of WorkWell, as well as a specification of the target DIW interface.This technology is valuable to any organization where users must operate in information dense and time critical environments. WorkWell will allow the application of work-centered design techniques within today's time-constrained software development.

COGNITECH CORP. 1060 East 100 South, Suite 202 Salt Lake City, UT 84102
Phone: PI: Topic#:	(801) 322-0101 Dr. Wendell Duncan AF 01-069 Awarded: 12APR01
Title:	Toxicity Evaluation Module
Abstract:	Many chemicals have limited occupational health and toxicological data. A computerized fuzzy logic expert system module could synthesize information from diverse sources and support the assessment of a chemical's toxicity endpoints and associated uncertainty. The interdisciplinary team of toxicologists, chemists, and computer scientists will develop a fuzzy logic methodology and knowledge base for determining toxicity endpoints. The investigators will use this methodology to develop a prototype web-based fuzzy logic expert system, integrated with an interactive user interface and database. The investigators will create the knowledge base rules and facts from QSAR-related variables (i.e., chemical physical properties) and existing toxicological data. This software will be evaluated and demonstrated with the adrenocortical endocrine disruption toxicity endpoint. Phase II will extend Phase I's methodology and technologies to develop a fully functional software prototype that will estimate health hazards over a larger spectrum of toxicity endpoints relevant to the Air Force.The toxicology decision support module will have applications as an initial screening mechanism for industrial chemical manufacturers and their customers. An additional market is as an educational tool for universities, hospitals, and emergency response agencies.

INTELLIGENT AUTOMATION CORP. 10299 Scripps Trail, PMB 231 San Diego, CA 92131
Phone: PI: Topic#:	(858) 679-4140 Dr. Dariusz Wroblewski AF 01-069 Awarded: 25APR01
Title:	Computional Framework for Intelligent Predictive Toxicology
Abstract:	The ability to rapidly assess the human health risks posed by a multitude of newly developed chemical compounds is of critical importance. Standard method for predicting toxicity to humans involves in vivo testing in laboratory animals. High cost and time requirements of the animal studies created an interest in the development of predictive toxicology, in which the toxicity inferences are obtained from a limited number of animal studies with the use of additional, more easily obtainable information such as results of in vitro studies, and/or physical and chemical properties of the molecules. Although a substantial progress has been achieved in development of methods of predictive toxicology, there is no definitive method (computational or, biological) that can be relied upon in the prediction of human toxicity. IAC proposes to develop the iPTE (Intelligent Predictive Toxicology System), an open-architecture computational framework for development and integration of predictive methods. In Phase I, the system architecture will be designed and a prototype will be demonstrated for a single toxicity end-point. The Phase I research will include implementation of novel neural network classification techniques and development of reliable quantitative measures of the prediction accuracy. The computational system for toxicity prediction is a significant product that will be used for both civilian and military applications. The main function of the system will be to provide rapid screening of newly developed chemicals with respect to human toxicity. Such screening is required by regulatory requirements for various industries. Additionally, the system may be marketed as an integration and development platform for emerging predictive approaches

RATIONAL DISCOVERY LLC 114 Brenton Ct. Mountain View, CA 94043
Phone: PI: Topic#:	(650) 691-9753 Dr. Hugh Genin AF 01-069 Awarded: 26APR01
Title:	An Adaptive, Modular Machine Learning System for Toxicity Prediction
Abstract:	We propose an innovative approach to the development of toxicity evaluation software. We will adapt a modular machine-learning software system that was originally designed for modeling inorganic and organometallic substances in catalysis and materials science problems to the challenge of predicting toxicity endpoints for a wide range of chemicals. The software's descriptor-based representation of substances allows us to generalize this modeling system and to simultaneously include many different types of chemicals. The modular nature of the software allows us to create multiple models for different toxicity endpoints one by one, and then combine them seamlessly into a final product giving one prediction along with a degree of confidence in that prediction. Due to the nature of the machine-learning approaches being applied, the reliability of the predictions will improve as more data are used to train each module. Phase I of this research will demonstrate the ability of this software to predict acute lethality as represented by oral rat LD50 values and to provide measures of confidence for those predictions. Phase II will involve creating and combining modules for other toxicity endpoints and will also involve training on human toxicological data.The Air Force and other DoD components must perform risk-assessment determinations on all the new (and some existing) chemical entities that they develop and deploy. Current methods of toxicological studies are slow and expensive. The benefits to DoD of an alternative method such as the computational model proposed herein will be to speed the rate at which chemical substances can be evaluated and lower the cost of those evaluations. Other government agencies (e.g., NIST, EPA, FDA) also have a need for toxicological evaluation software to streamline their risk-assessment procedures. In private industry, the need to perform toxicological evaluations is present and growing in the chemical manufacturing, agricultural, and pharmaceutical sectors, to name only a few. New substances are continually being developed, and stricter government regulations require that more of them be tested, at a cost in time, dollars, and animal lives that can reach staggering proportions. Effective toxicity evaluation software will save enormous amounts of time and money. The market for alternative toxicity evaluation techniques is large and is expected to continue to grow.

YAHSGS LLC 8516 Oxford Drive Knoxville, TN 37922
Phone: PI: Topic#:	(865) 607-2988 Dr. Katherine Yuracko AF 01-069 Awarded: 02MAY01
Title:	Chemical and Material Toxicity Evaluation Module
Abstract:	The U.S. Air Force deploys and encounters a highly diverse spectrum of chemicals and materials. The health hazards of these materials must be evaluated to protect personnel and to minimize life cycle costs for weapon systems. To evaluate health risks, chemical toxicity information is needed. However such information is costly and requires several years of testing to obtain. As a result, reliable data are available for only a few percent of the chemicals in use today. The research under this Phase I SBIR project is directed at demonstrating the feasibility of using artificial intelligence approaches to estimate human health risks from exposure to chemical hazards. To accomplish this feasibility demonstration, a chemical toxicity database will be designed and developed to underpin predictions of genotoxicity, carcinogenicity, and developmental/reproductive toxicity for chemicals of interest to the Air Force. Both a neural network and statistical techniques will be used to predict these three toxicity endpoints, and the performance of the two approaches compared. Technical feasibility will be demonstrated by achieving a 90 percent or better accuracy in predicting toxicity for chemicals of interest to the Air Force. This level of performance represents a significant improvement over currently available systems.If proven feasible during Phase I, YAHSGS' approach to predicting chemical toxicity will provide a rapid and inexpensive means to determine the health risks of new chemicals; the risks of existing chemicals for which inadequate toxicity data exist for conducting health hazard assessments (~80% of chemicals in commercial use); and risks for chemicals encountered in military and industrial situations. The Chemical and Material Toxicity Evaluation Module (CAMTEM) will be sold either as an application for installation on a user's system or as a tool to be used via Online Analytical Processing (OLAP). The OLAP approach will greatly expand the user group and market potential by reducing the user's hardware, software, and, potentially, training requirements. Two specialized modules will be developed to expand the CAMTEM's usage and marketability to government and industrial users. The first will predict environmental effects of subject chemicals including the risks associated with chemical daughter products formed or released to the environment. The second will provide reverse engineering capabilities that will identify ways for chemical designers to eliminate or reduce health risks from chemicals or products being developed. The overall benefit from the CAMTEM approach will be the availability of significantly better health risk information for the 80% or more of the chemicals now in commercial use for which there are currently inadequate toxicity risk related information and for new chemicals being developed. That information will enhance governments' and industries' ability to recognize specific chemical toxicity related risks and take responsible steps to avoid exposing people and the environment to harmful chemicals.

SYSTRAN FEDERAL CORP. 4027 Colonel Glenn Highway, Suite 210 Dayton, OH 45431
Phone: PI: Topic#:	(937) 429-9008 Mr. Paul Rudolph AF 01-075 Selected for Award
Title:	Remote Consolidated Data Loader
Abstract:	In currently Air Force operations, mission planning data is generated using a ground-based system, and is then hand carried to the aircraft shortly before takeoff. To allow more time for the mission planning operations, the Air Force would like to be able to use wireless data transmission to transfer this data. SFC proposes to develop a Remote Consolidated Data Loader (RCDL) to meet this need. The RCDL will use a COTS wireless technology to transfer data from the Mission Planning System (MPS) to the aircraft. In a previous SBIR, SFC has developed a prototype wireless maintenance tool, called PALM-IT, which has many of the features desired for the RCDL. SFC intended to leverage this experience in developing the RCDL; as part of Phase I, this prototype will be modified to support the functions needed by the RCDL. During Phase I, we will define the hardware and software requirements for the RCDL, select the COTS wireless technology to be used, evaluate the COMSEC requirements and select an NSA-approved encryption standard, and gather requirements from potential users of the RCDL, and develop a top-level design. The RCDL system will be flight-tested during Phase II aboard a Combat Talon I aircraft.By eliminating the time spent hand-carrying the mission planning data to the aircraft, the RCDL system will allow a larger amount of pre-flight time to be devoted to mission planning. This can be a significant benefit, particularly when operating in a high-tempo environment. By utilizing NSA-approved Type I encryption standards, RCDL will provide a high degree of data security, while eliminating the need for the portable media currently in use. By offering future compatibility with GATM systems to be fielded within the next decade, RCDL will eventually be able to support in-flight data transfers, allowing mission planning and other information to be updated even while a mission is in progress.

CYCORP, INC. 3721 Executive Center Drive, Suite 100 Austin, TX 78731
Phone: PI: Topic#:	(512) 514-2976 Mr. William Wechtenhiser AF 01-078 Selected for Award
Title:	Using Cyc(R) Technology to Create an Intelligent Network Configuration Tool
Abstract:	Investigate how to improve not just the precision and accuracy of network configuration tools but also how to qualitatively expand the scope of what sorts of conditions of interest they report, by incorporating a large commonsense knowledge base to enable reasoning about network functionality. Current tools are limited by their inability to consider all the factors that bear on network configuration analysis, including adherence to policies, network functionality, network design tradeoffs, and real-world factors (e.g., weather, holidays, physical layouts of offices, and so on). To make this happen, the network, the policies, etc. would have to be declaratively represented in a formal language such as CycL (predicate calculus). Then a base of general knowledge similarly represented - e.g. the Cyc KB - could be brought to bear, along with the deductive reasoning engine associated with that KB. Altogether, this could be a power tool for the network administrator, enabling them to detect multi-step conditions of interest (e.g., vulnerabilities) and to perform "what-if" analyses of proposed changes in the network without having to actually make the changes and run diagnostics.Success in this endeavor will greatly simplify the network administrator's job, and thus improve both the stability and security of the network in question. Furthermore, this technology will advance the state of the art in network analysis by adding a layer of intelligence while permitting network administrators to evaluate hypothetical configuration changes without actually reconfiguring the network.

STOTTLER HENKE ASSOC., INC. 1660 So. Amphlett Blvd., Suite 350 San Mateo, CA 94402
Phone: PI: Topic#:	(650) 655-7242 Mr. Richard Stottler AF 01-078 Selected for Award
Title:	Optimizing Network Configuration Toolkit: via an AI Interface to OpNet's Modeler Commercial Simulation Engine
Abstract:	We propose to develop an innovative Artificial Intelligence (AI) toolkit interface to OPNET Modeler, a COTS simulation engine, to configure and optimize network configuration and operations in the field. This toolkit will allow rapid design and optimization of communications networks without requiring the user to have programming skills or knowledge of the underlying OPNET Modeler simulation engine. Because developing such a toolkit represents a challenge, we suggest an integrated approach drawing upon a broad range of AI techniques, user interface, and visualization technologies. There is currently a great need for any solution that will dramatically reduce the complexity of network configuration due to the great quantity and diversity of information that must be analyzed, as well as the short decision cycles. The resulting system will provide the capability for less experienced network engineers to perform efficient and effective network engineering and ongoing operations, with the end result being reduced costs, increased operational efficiency, and improved robustness. We will absolutely demonstrate the feasibility of our ideas through the development of a Phase I, proof-of-concept prototype. The enormous opportunities for both commercial and governmental applications include use on all types of communications networks; optimizing based on utilization, cost, and performance.

ARCHITECTURE TECHNOLOGY CORP. 9971 Valley View Road Eden Prairie, MN 55344
Phone: PI: Topic#:	(952) 829-5864 Mr. Jmaes A. Newhouse AF 01-080 Selected for Award
Title:	Common Data Access Models and Services Using Datalets
Abstract:	The Air Force needs to access a large variety of databases with varying data schemas and storage architectures from an equally large variety of applications. This presents a rewarding but challenging problem of enabling access to these databases via common data access models and services. This problem, and also its most challenging implementation aspect, is particularly significant in the context of mission planning, where time constraints make it critical to obtain timely access to data required for optimal plan generation. This project will investigate using a novel concept called "datalets" for implementing common data access models and services in the context of the "Theater Battle Management Core Systems (TBMCS)" application domain. The effort will be compatible with the overall approach of the "Joint Battlespace Infosphere (JBI)" program. The research will leverage state-of-the-art technologies such as various XML protocols and agent-based programming. This research has both military and commercial benefits. The military benefit would be a significant advancement in the architecture for the TBMCS in particular and the JBI in general, potentially providing an approach that would become an integral component of the JBI program. In commercial applications, the datalet paradigm could become a new tool for easy access to disparate data from disparate Web-based applications across a broad spectrum of distributed, enterprise, and business-to-business commercial applications.

SCHWALB CONSULTING, LLC 26 Valley View Irvine, CA 92612
Phone: PI: Topic#:	(949) 856-0291 Dr. Edward M. Schwalb AF 01-080 Selected for Award
Title:	Common Data Access Models and Services
Abstract:	We propose to develop an intelligent self-reorganizing middleware providing access services that are independent of data sources and that provide a common simultaneous access for various clients running on multiple platforms. Presented below are (1) the technology, (2) the killer application, (3) highlights of a B-Plan and (4) Phase I work plan. This project will utilize the Java-based Nodes API (NAPI) technology, which is a highly efficient object-access technology managing 4-layered caching mechanism. NAPI is unique in that it anticipates which objects that are likely to be requested, and pushes these objects through the cache pipeline; it is asynchronous, thus enable populating the cache pipeline through background processes while delivering instantaneous client response. The proposed killer application presents an opportunity to overhaul of the current casualty reporting system and redefine the acquisition and distribution of medical situations and needs; it will be designed with a focus on ultra-fast response for effective crisis management. NAPI was successfully used to implement diverse application such as a knowledge visualization tool, and a patient record abstraction and visualization tool. In this project, NAPI will be extended to support Office Automation (OA) tools and email client. NAPI has the potential of simultaneously reducing the development costs and improving the performance of applications that require access to persistence object storage through a middleware component. This potential can be realized through the integration with leading application servers, such as WebSphere (IBM) and WebLogic (BEA Systems).

COMCEPT, INC. 209 East IH-30 Rockwall, TX 75087
Phone: PI: Topic#:	(972) 772-7501 Mr. Mike Greer AF 01-082 Selected for Award
Title:	Improvement to Geo-Registration
Abstract:	Today, Ground Moving Target Indicator (GMTI) assets operate independently and report their information on separate communication systems. Each of these systems uses different host platforms, navigation systems, GMTI sensors, processing algorithms, and communications systems. Each of these sensors has its own inherent set of error sources that affect the accuracy of the derived geolocation. These errors may be inherent in the location of the sensing platform itself, may result from the way that the basic sensor data is collected and measured, and may be introduced by coordinate system and datum transformations that govern the processing of collected data. ComCept has extensive experience in developing geolocation algorithms and simulations for network centric collaboration of assets, as well as GMTI track enhancements. ComCept proposes to leverage from research and algorithm development on their Network Centric Collaborative Targeting Network Simulator (NNS) effort, their Geolocation - ComCept Analysis Tool (GeoCAT) effort, and their subcontract effort for Northrop Grumman on GMTI track enhancement to design and develop a new geo-registration tool, called GeoLock, that will demonstrate the benefits of geo-registration on geolocation performance.The future commander must have the ability to overcome current geolocation disparities to locate and identify potential threats quickly before they can react. New algorithms that increase the speed and accuracy of geolocation performance by removing these disparities have the potential to save lives and avoid casualties. Geo-registration has proven to be a method for significantly improving geolocation performance. The geo-registration tool that ComCept develops through this Phase I effort, called GeoLock, will give USAF program managers, mission planners, and analysts a method for modeling and simulating geolocation performance and the improvements fostered by geo-registration. Because the geo-registration process is standard, GeoLock is not limited to use by GMTI platforms only. It applies equally as well to all military and commercial assets and forces that have a need for geolocation and geo-registration. Other military applications include the Navy Cooperative Engagement Capability (CEC) effort and the US Coast Guard Deepwater Project. Two commercial examples are law enforcement and emergency services concerned with locating target radios.

DUBBS & SEVERINO, INC. 606 Larkridge Irvine, CA 92618
Phone: PI: Topic#:	(949) 262-0535 Ms. Kimberly Dubbs AF 01-083 Selected for Award
Title:	Demonstrate Track Management Concepts for Exchange of GMTI Track Information
Abstract:	The sharing of military data on the battlefield is currently an incredibly complex process. The computers, communication devices, weapons systems, and sensors deployed by the various services lack standardized interfaces, require excessive support, and suffer myriad problems that impede the effective flow of information during combat operations. The proposed GeoSystem client/server track manager is an integrated toolkit which will address this problem. Using industry standards for information transport that have evolved with the Internet, the GeoSystem will provide the infrastructure required to ensure secure, real-time data flow on the battlefield. During this Phase I effort, we will build on some of our existing track-manager software to produce a prototype that will include all the functionality required of a system suitable for actual field deployment. The aviation safety community, biological monitors, climate modelers, surveyors, oil-explorers, and certain types of mineral excavators all face track-management problems similar to those faced by the Air Force. The technologies we propose to develop during this Phase I effort could all be adapted to support these endeavors.

INTEGRATED SENSORS, INC. 502 Court St., Suite 210 Utica, NY 13502
Phone: PI: Topic#:	(315) 798-1377 Mr. Walt Szczepanski AF 01-084 Selected for Award
Title:	FOPEN SAR Enhancements
Abstract:	This proposal addresses two problematic issues with GMTI (Ground Moving Target Indicator) radar surveillance systems. First, when the Doppler velocity of a vehicle drops, a GMTI system cannot detect it (e.g. the "move-stop-move" problem). Second, a vehicle is only detectable at intermittent intervals when moving under dense foliage. Because of its low frequency, FOPEN SAR can detect targets under foliage. GMTI detection techniques developed for a combined monostatic / bistatic FOPEN-SAR (Foliage Penetrating Synthetic Aperture Radar) system will track the vehicle during GMTI blind stages. A GMTI system hands the track to the SAR system when the target slows. When the target resumes speed, the SAR system hands it back. Unless the Doppler velocity is zero, there will be a cross-range bias in the detected target location. Therefore, the Doppler velocity is measured in order to compensate. Although FOPEN SAR lacks the resolution to identify targets at reasonable integration times, the proposed system will merge otherwise disjoint tracks to correctly associate them with the proper target. Such information will facilitate the identification process. This effort will compliment an upcoming GMTI radar Phase II effort, where a combined FOPEN-SAR/GMTI system utilizes a common antenna array. Commercialization potential includes drug enforcement applications, where there is also a need to spot moving vehicles under forested canopies. These techniques are also applicable to high frequency radars when the targets are visible.

TECHNOLOGY SERVICE CORP. 11400 West Olympic Blvd., Suite 300 Los Angeles, CA 90064
Phone: PI: Topic#:	(310) 954-2200 Mr. Joseph Salzman AF 01-084 Selected for Award
Title:	FOPEN SAR Enhancements
Abstract:	One of the most promising approaches to alleviating the limitations of detecting and targeting time-critical, fixed and mobile ground targets that use CC&D techniques, is the use of FOPEN radars. These radars, which operate in the VHF/UHF bands using UWB techniques, can obtain high-resolution (~ 0.5 m) SAR images of concealed targets. However, using these FOPEN SAR images to detect man-made targets distributed over vast areas in deep forest cover or other camouflage, has long been recognized as important but difficult. The foliage complicates the detection process in a number of ways, but the most challenging is the backscatter from the tree trunks and areas adjacent to the targets - often indistinguishable from the target returns. To enhance target detection - and subsequent tracking and recognition - TSC is proposing a novel approach that exploits the image recovery attributes of auto-regressive (AR) techniques, such as the Burg algorithm. The technique holds great promise in providing a means to discriminate true target returns from discrete tree trunks and other clutter. During Phase I, TSC will investigate the feasibility of exploiting FOPEN SAR image notching and AR recovery techniques to enhance the detection and eventual track and recognition of ground targets moving in forested areas. The technology developed in this project will result in a robust method for the detection - and eventual track and recognition - of true ground target returns amid myriad returns from tree trunks and other clutter, with low false-alarm and missed targets. The technology is expected to substantially improve the military's effectiveness in targeting concealed fixed and mobile ground targets. In addition, it has civilian applications which include forestry monitoring by environmental services for compliance with logging restrictions as well as forest fire fighting, and law enforcement and drug traffic interdiction in heavily forested regions like South America.

IRVINE SENSORS CORP. 3001 Redhill Avenue, Building #4 Costa Mesa, CA 92626
Phone: PI: Topic#:	(714) 444-8715 Dr. Volkan H. Ozguz AF 01-085 Selected for Award
Title:	Stacked Adaptive Computing Module
Abstract:	ISC proposes to develop an adapative computing module using stacked commercially available, programmable gate arrays (FPGAs), processors and memories to provide a universal hardware commonality which will ease system design and delay obsolescence. It will also alleviate the need for ASIC processors and controllers in many applications, as RISC versions of high-end microprocessors can also be emulated. Using currently available FPGAs, it will be even be possible to reconfigure on-the-fly, such that software for different platforms may be run on the same system, with the transitions being transparent to the user. Projecting a step further, developers may be able to customize the behavior of the processor to optimize for a specific complex task, or mix and match the best of multiple processors, all within software. ISC is in a unique position to develop such a system. Using a novel 3D stacking method, we can turn a prototype system of COTS components into a monolithic device, bypassing the IC design and wafer manufacturing steps. This approach has the added benefit that we can readily upgrade the system as the component COTS technologies are advanced. The complexity and the performance improvement provided by stacking will allow the stacked modules to have performance similar to monolithic ASICs.This module can serve the needs of data mining and data processing applications. Developed technology can be applied as a service to OEM and other industrial or governmental institutions in need of a long term solution to changing processor needs for a large variety of applications.

MISSION RESEARCH CORP. 735 State Street Santa Barbara, CA 93101
Phone: PI: Topic#:	(505) 768-7788 Mr. Daniel King AF 01-085 Selected for Award
Title:	Development of a Radiation Hardened Wafer Scale Signal Processor
Abstract:	The development of a radiation hardened WSSP (Wafer Scale Signal Processor) is proposed. The project will result in a high performance, programmable, floating point dual processor. Radiation hardening will be designed for environments including total ionizing dose (>300 Krad(Si)), dose rate upset (>1011 rad(Si)/s), latchup (immune to both dose rate and single event latchup), and single event effects (<1x10^-10 errors per bit day). The WSSP is specifically designed for fault tolerance and power efficient, sustained floating point performance. It is optimized for efficient memory utilization with each of the dual processing elements capable of accessing either of two independent memory banks over two 72 bit (64 bits plus byte parity) buses. The WSSP can perform 8 single precision floating point operations per clock cycle. The Phase 1 effort will result in a high level partitioning of the rad hard design into synthesizeable macros. A series of analyses will be performed to demonstrate the ability to achieve hardness required for strategic systems. The detailed design and fabrication of the RH-WSSP in a state-of-the-art SOI process will be performed in Phase 2.A radiation hardened WSSP will provide an enabling technology for high performance, digital signal processing in space. The WSSP is optimized for MFLOPS/Watt, which is the critical metric for the floating point intensive applications encountered in next generation space systems.

RADANT TECHNOLOGIES, INC. 255 Hudson Road Stow, MA 01775
Phone: PI: Topic#:	(978) 562-3866 Dr. Fredric Ziolkowski AF 01-086 Selected for Award
Title:	Dome Lens with Hemispherical Scan Coverage for Milstar Airborne Applications
Abstract:	Airborne MILSTAR SATCOM Terminals require at least hemispherical coverage. In principle, the Dome Lens can expand the less than hemispherical coverage of a single electronically scanned array or of a limited mechanical scan antenna to a more than hemispherical coverage. This effort aims to evolve practical design concepts for a Dome Lens addressing the unique requirements of EHF frequencies and the airborne environment. This research could lead to a SATCOM terminal designs requiring only one (1) antenna to provide full operationally required coverage. This represents cost savings and a solution to on-aircraft installation problems relative to multiple antenna solutions.

PRINCETON MICROWAVE TECHNOLOGY, INC. UNIT C-10, 3 NAMI LANE MERCERVILLE, NJ 08619
Phone: PI: Topic#:	(609) 586-8140 Mr. Sarjit S Bharj AF 01-087 Selected for Award
Title:	High Efficiency, Small Volume 44 GHz Transmitters
Abstract:	The replacement of millimeter-wave traveling wave tube by solid-state power amplifiers has been recognised as a very important goal for some time. Solid-state power amplifiers provide the substantial benefits of elimination of high voltage supplies, reduction in size and weight, and generally improved reliability, especially for airborne microwave systems. Hoever, the demans of higher power at higher frequencies are stedily increasing in today's molitary and commercial applications such as MILSTAR, SATCOM, GBS and LMDS. The limitation of output power capability of state of art solid state devices can be partially overcome by combining several devices or amplifiers. A difficult aspect of designing a combiner is finding a scheme that offers low loss, good amplitude and phase balance, and high power handling capability.Combining approaches cccan be seperated into two groups: those which combine two devices at a time(binary) and those that combine the output of N devices in one step(n-way combiners).On one hand, the losses of binary structures degrade the combining efficiency and on the other hand, the n-way combining structures are designed to combine the output of N devices in one step. This scheme has the potential for a higher combining efficiency.We propose the development of MILSTAR SSPA using a radial combinerThe development of the SSPA amplifiers for SATCOM, and GBS will find direct insertion into Local Multi-point distribution Systems at 28-30 Ghz in which Princeton Microwave is currently active.

SOPHIA INTERCONNECT TECHNOLOGIES, INC. 14225-C Sullyfield Circle Chantilly, VA 20151
Phone: PI: Topic#:	(703) 961-9573 Mr. Philip J. Koh AF 01-088 Selected for Award
Title:	Development of extremely compact, low cost millimeter wave up and down converters with rapid frequency agility
Abstract:	We propose to develop frequency hopping millimeter wave oscillators for integration with our compact up/down converter architecture to develop compact, low cost solutions for MILSTAR and GBS transceivers.Commercial Point-to-point and point-to-multipoint fixed wireless links, LMDS, and satellite communications systems.

TOYON RESEARCH CORP. 75 Aero Camino, Suite A Goleta, CA 93117
Phone: PI: Topic#:	(805) 968-6787 Dr. Scott May AF 01-089 Selected for Award
Title:	Agent-Based Algorithms to Search Multiple Databases for Spatial and Temporal Information
Abstract:	In future military operations, intelligence analysts will have access to unprecedented quantities of surveillance data. Toyon proposes to develop an architecture that employs "intelligent software agents" to reduce information overload for the operator by automating many of the intelligence processes. This architecture will also be robust with respect to changing network conditions. The architecture consists of three categories of intelligent software agents: User-Interface Agents, Task Agents, and Information Agents. The User-Interface Agents translate user commands into requests for the Task and Information Agents. The Task Agents automate many intelligence-analyst tasks by using data synthesis algorithms. The Information Agents respond to requests for data by searching the data sources at their network location. The intelligent agent architecture will be developed using a simulated intelligence, surveillance, and reconnaissance sensor network. Functions that the proposed architecture will enable include tracking with ground-moving-target-indicator (GMTI) radar, track-level fusion between multiple track databases, and multi-sensor data fusion. At the conclusion of Phase I, Toyon will demonstrate the system architecture using a simplified user interface and a small set of rules to govern the behavior of the Task Agents. The successful completion of this research will result in a system that the Air Force and others can use to gather data across a network from multiple data sources. Specific customers within the Air Force include the JSTARS SPO, the AFRL TUT program, and other programs that synthesize data across the network. Many other government agencies as well as private industry could use the technology for related data-synthesis applications.

COMPUTER GRAPHICS SYSTEMS DEVELOPMENT 2483 Old Middlefield Way #140 Mountain View, CA 94043
Phone: PI: Topic#:	(650) 903-4922 Mr. Roy W. Latham AF 01-090 Selected for Award
Title:	3-D Display of Time Critical Targets on Joint STARS Operator Workstation
Abstract:	The complexity of the modern battlespace and the extent of information supplied by modern sensors makes traditional methods of data display ineffective for efficient decision making. For the present effort, alternative approaches will be studied based upon three recent advances in technology, specifically (1) automatic tracking technology, including multiple hypothesis tracking and optimal estimation approaches; (2) real time data visualization techniques, including parametric object building, made possible by advances in graphics hardware; and (3) Network-based information dissemination, including person-to-person and system-to-system collaboration.The targeted military benefit is improved decision making in the ground moving target sensor environment, and more generally in complex battlespaces. Commercial applications include weather prediction from voluminous weather sensor data and financial analysis and prediction in very complex financial data environments.

ANDRO CONSULTING SERVICES Beeches Technical Campus, Bldg. 3, Ste. 4, Rt. 26N Rome, NY 13440
Phone: PI: Topic#:	(315) 334-1163 Mr. Andrew L. Drozd AF 01-091 Selected for Award
Title:	Situation Awareness Information Fusion: ANDRO's InFuSA System - A 4D Modular Virtual Crew Station Applying Visual/Auditory Display Surround For Rapid
Abstract:	New fighter/bomber air defense crews and airborne C4I surveillance operators encounter ever-increasing amounts and types of real time information from on- and off-board sensors and other information sources. The problem is complicated by the increasing number of off-board military platforms providing situation awareness (SA) information on hundreds of different targets and tracks, and the assessment of merged/processed data from multiple sources. For instance, the SA of the complex battlespace for ground moving vehicle time critical targets including detecting tanks under trees involves the assessment of large amounts of real time, near real time, and non real time data. These growing demands place undue information processing requirements on aircrews and operators that can lead to spatial disorientation, loss of situational awareness, cognitive overload, and delayed reactions during emergency or transient conditions. This forces personnel to function as human data integrators rather than as decision makers. These potentially dangerous conditions underscore the need to supply operators or aircrews with manageable amounts of high-quality information. One method for accomplishing this goal is to address the requirement of providing a single SA picture to the crew. This visualization will be customizable to each individual's needs providing different levels of details, but with a single data set. Customization can be achieved with data mining, contact layer drill down, ability to aggregate or dis-aggregate information. The single data set ensures synchronization and a reliable measurement of uncertainty of time. This requires the development of a new capability to effectively fuse information and present an integrated SA picture that exploits modern visualization/display and multi-modal user control technologies to facilitate ease of interaction with on-board information systems and support rapid decision making. Current human-computer interfaces (HCIs) are often the bottleneck in effectively and efficiently utilizing the available information flow for decision making. This is increasingly true with greater demands for processing speed, throughput, and data storage. Recent advances in sensor fusion and display technology can be synergistically exploited to develop novel HCIs and control systems to reduce confusion on the part of aircrews of the future. Information rich environments require a user-centered approach that adapts to heterogeneous changing connections of information sources and devices with multiple modalities such as gesture/speech recognition, eye gaze, lip reading, and even biofeedback mechanisms attached directly to crewmembers. These multi-modal environments must also be interoperable. The integration of multi-modal inputs for human-machine interaction is approached from the viewpoint of multiple information source fusion where different information sources can be related to different interface modalities to establish an interoperable multi-disciplinary SA fusion system. This system would provide aircrews and operators from multiple disciplines (tactical C2, strategic surveillance, EW, etc.) and those interfacing with on-board bomber/fighter platform (B-2, Joint Strikes Fighter, etc.) and off-board surveillance system (AWACS, Joint STARS) sensors, or with supporting DoD acquisition centers (B-2 and JSF SPOs) with a common set of augmented reality display formats and user controls. The new displays and multi-modal control schemes will be readily useable by a sensor to shooter cockpit warfighter, operator, or battlespace commander across various computer display platforms with little or no training. Traditional analog instruments and gauges would be replaced with large, flat-panel multi-function displays that combine the functions of separate instruments into a multifunction workstation. A new digital cockpit would provide pilots and operators with equipment that is more intuitive, easier to use in real time, and less expensive than today's avionics equipment. Much of this new technology would take maximum advantage of existing COTS technologies to lower development costs and increase commercialization potential. The Phase I program objective is to develop and demonstrate interoperable SA using multiple HCI modalities capable of fusing information into a consistent operational picture. This will result in the development of a generalized architecture with appropriate models and techniques for SA information fusion called the Information Fusion for Situation Awareness (InFuSA). This initiative will develop and demonstrate a real-time data fusion architecture with appropriate models and techniques, merging data from multiple sources such as Link-16, intelligence data links, and on-board sensors to form a single common SA picture. It will involve combining knowledge of the application domain with the ability to express application-specific actions, objectives, and qualifiers to improve the ability to conceptualize and visualize information to enhance collaborative decision making as well as continuously monitor and update present and future battlespace awareness states. The focus is on the development of a data fusion architecture within the context of an improved operator machine interface environment. The proposed InFuSA system, which will adapt the Air Force's "Super Cockpit" concept, represents a next-generation visualization/display and operator control capability for future DoD information management systems. It also addresses identifiable MAJCOM and dual use sector deficiencies, and USAF infrastructure needs consistent with the Integrated C2 and Joint Battlespace Infosphere (JBI) frameworks which are connected to, and interoperable with, C2 and combat support information systems. This advanced capability can be used to convert complex multi-discipline and multi-sensor data into SA metrics to support integrated C2, JBI, and C4I goals for "digitally" assessing combat situations.The ability to incorporate large amounts of electronic flight information into control stations that can be managed with great ease and minimal training has the potential of revolutionizing the general aviation sector. Safe and effective control has implications in other control room and control station scenarios including the operating room of a hospital, building management and safety, nuclear power plants, emergency and life support services, and the interactive workplace of the future. The algorithms and visual techniques are also applicable to any commercial industry that evaluates large amounts of data from real-time to historical data in order to determine the current state of the environment and analyze or forecast future trends. Cross discipline applications include 3-D displays for biologists, chemists, and other scientists, the virtual operating room, simulation control, commercial aircraft, air traffic control, and salvage, search and rescue management. Other potential civilian/dual use applications include: financial markets, traffic analysis in major cities, manufacturing and operations research applications, medical diagnostics, meteorology and weather forecasting, airborne and satellite-based imaging; security systems, concealed weapons detection, medical imaging, chemical tomography, computer vision, airborne hyperspectral analysis, environmental monitoring, ordnance detection, 3-D effects software, and geographical information system (GIS) applications.

GALORATH, INC. 100 North Sepulveda Blvd, Suite 1801 El Segundo, CA 90245
Phone: PI: Topic#:	(310) 414-3222 Mr. Dan Galorath AF 01-092 Selected for Award
Title:	Estimation of Manufacturing Cost and Risks for Satellite Electro-Optical Sensors
Abstract:	Earth observation via satellites currently provide valuable data in a wide range of fields such as topography, oceanography, atmospheric conditions, biological distribution, and climate. The United States Air Force, Navy, NASA, and private industry have launched a variety of observation satellites, and the Air Force has always taken a primary role in research for developing these satellites and sensors. Electro-optical sensors perform a key role in accomplishing these missions. As with all cutting edge technology, the production of complex assemblies in relatively small quantities is an expensive learning process. The decision to develop a mission-critical electro-optical sensor requires both technical design information and cost/affordability data, as well as an understanding of the relationship between the two and the inherent technical and cost risk. We propose to explore the use of new and innovative mathematical theories coupled with more traditional product- and process-based parametrics to quickly yet accurately estimate costs for an elector-optical sensor assembly. We will also couple automated design tools (CAD/CAM) to automated cost tools, providing the capability to examine both the technical and cost implications for a wide range of design options. The results of this project may be expected to provide substantial commercial benefits by enhancing Galorath's current line of parametric cost, schedule and risk software tools. This research will enhance the capabilities of the tools to estimate cost and risk for satellite electro-optical sensors, and Galorath expects to be able to extend this range of applicability to other, similar complex assemblies. This capability will prove very interesting to current and potential customers of our hardware development and design-for-manufacturability tools. In addition, Galorath has already identified among both current and potential customers a strong desire for feature-based estimation capabilities which are automatically linked to CAD/CAM design tools.

THE ATHENA GROUP, INC. 3424 N.W. 31 Street Gainesville, FL 32605
Phone: PI: Topic#:	(352) 371-2567 Dr. Jonathon D. Mellott AF 01-093 Selected for Award
Title:	A Low Power FFT/IFFT for GPS Applications
Abstract:	The Athena Group will develop an innovative, low-power, fast Fourier transform (FFT) processor for use in mitigating both intentional and unintentional narrowband jamming and interference in handheld global positioning system (GPS) receivers. Athena's advanced digital signal processing (DSP) technology is capable of performance levels well beyond those of conventional DSP technologies. Athena will analyze the processing requirements for the GPS receiver application, select an FFT processor configuration along with pre- and post-FFT processing elements, and analyze the resulting design for speed, power, and hardware requirements. The proposer will optimize a solution that will lead to a commercial system-on-chip (SoC) anti-jam GPS application-specific integrated circuit (ASIC) implementation.The commercial value of the developed technology is substantial since it will significantly improve the reliability and quality of GPS service. GPS applications are proliferating, especially in the land-based market segment. Numerous other mass-market FFT ASIC applications, such as asymmetric digital subscriber loop (ADSL) modems and orthogonal frequency division multiplexing (OFDM) wireless communications, also indicate a high market potential for the proposed technology.

GALORATH, INC. 100 North Sepulveda Blvd, Suite 1801 El Segundo, CA 90245
Phone: PI: Topic#:	(310) 414-3222 Mr. Lee Fischman AF 01-094 Selected for Award
Title:	A Software Cost Model Based on Software Architecture
Abstract:	This proposal outlines the development of an automatic sizing tool. The tool will interface with off-the-shelf "CAD" design tools for software, to the extent necessary for design information to be read in and sized. Sizing information will be automatically converted to function points. Underlying development of this tool is considerable Galorath's considerable applied research, and our identification of potentially key enabling technologies, such as genetic and parsing algorithms. Information about software complexity may also be collected, to the extent practical, useful and coincident with the primary objective of this SBIR. The tool will be developed so that it easily interfaces with commercial software estimation models.This research into automatic sizing, and the resulting prototype tool, will be further developed into a robust standalone software product. We will develop a pricing and marketing strategy that lets us sell to the widest possible audience, keeping in mind that object-oriented and other "CAD" design methods are gaining very wide use in general industry.

TRLOKOM 124 Vista Circle Dr. Sierra Madre, CA 91024
Phone: PI: Topic#:	(626) 836-5545 Dr. Jayant Shukla AF 01-097 Selected for Award
Title:	Voice Authenticated Wireless Communication
Abstract:	Trlokom proposes to develop a novel and low cost solution for local speech processing and secure voice communication in digital wireless systems. Commercially available wireless communication systems do not have adequate security measures to ensure end-to-end secure communication. Since, wireless communication systems are now becoming very popular in military as well as in commercial world, providing end-to-end secure communication will reduce the danger of eavesdropping, credit-card theft, and industrial espionage. Our solution will be based on low-power and high-speed hardware for local processing of the speech signal. The same hardware will also assist in encryption, voice-authentication, protocol processing, and secure key-management. At the end of Phase I, we will deliver our design for an end-to-end secure wireless communication system with voice-authentication. We will provide detailed information about the component technologies and our integration methodology for the COTS and custom components. Digital cellular phone with internet access are starting to become available and we expect to see a big demand for security systems in digital wireless phones. Adding voice authentication to the security systems can make them much more user friendly and reduce the fraud associated with stolen phone. It could also be used with satellite telephone service (STS) to provide military with the ability to securely communicate where cellular phone service is not available.

SYSTRAN FEDERAL CORP. 4027 Colonel Glenn Highway, Suite 210 Dayton, OH 45431
Phone: PI: Topic#:	(937) 429-9008 Mr. Paul Rudolph AF 01-098 Selected for Award
Title:	Reconfigurable Integrated Fault Tolerance for Spaceborne Systems (RIFTSS)
Abstract:	Reconfigurable Computing (RC) is a technology in which the behavior of a processing system is changed by altering the hardware, rather than the software. This is achieved though the use of field programmable gate arrays (FPGAs). RC is useful when a high degree of both performance and flexibility is needed, and especially when size, weight, or power constraints preclude use of dedicated components for separate functions. The recent development of high-density, rad-hard FPGAs means that RC now has the potential to be used in spaceborne applications. SFC is currently developing an RC tool suite, called DERC (Development Environment for Reconfigurable Computing), which includes both hardware and software to support development of RC applications. RIFTSS will extend the capabilities of the DERC tools to include extensive support for fault tolerance. The DERC API and logic libraries will be extended to include fault tolerant functions, including configuration scrubbing, redundancy, and voting. The DERC Debug Tool will be modified to allow deliberate fault insertion into a design under test. To address system-level fault tolerance issues, this program will also evaluate several third-party modeling and simulation tools to determine how effectively they can handle the unique situations that will occur in fault tolerant RC.Reconfigurable Computing can provide both increased processing power and increased flexibility to systems that must perform a variety of different functions. This is especially important in systems for which weight, space, or power are at a premium (which make it particularly desirable in spaceborne applications). While RC has great potential, its use to date has been small, partly due to the limited number of development tools available. DERC will help enable greater use of RC technology by providing a comprehensive development system for the RC application developer. DERC includes a highly flexible hardware architecture and a full set of supporting software tools. The DERC hardware architecture is already well suited for fault tolerant designs. RIFTSS will extend the software tools to include support for design and testing of fault tolerant systems. Pre-tested fault tolerant logic functions will allow application developers to concentrate more effort on the functionality of the applications, rather than on fault tolerance. The ability to insert deliberate faults into the design under test will speed the testing process, and support improved reliability of the design.

WW TECHNOLOGY GROUP 4519 Mustering Drum Ellicott City, MD 21042
Phone: PI: Topic#:	(410) 418-4353 Dr. Chris Walter AF 01-098 Selected for Award
Title:	A Hardware-Software Codesign Framework for Scalable Reconfigurable Computing
Abstract:	The project goal is to construct and demonstrate an approach for building reconfigurable computing systems using reprogrammable logic arrays, FPGAs, under coordination of one or more processors leading to standardization of a process for reconfigurable computing applications using heterogeneous components and tools. The constraints on achieving these goals include the current limitations of available tools and the varying types of parallelism found in different applications. Within the scope of the project and identified applications, a software/hardware co-design process that leverages the effectiveness of reconfigurable components will be developed and evaluated, the methods and interfaces developed should support techniques and have universal application to other domains of interest. The approach consists of: (a) describing a hierarchical structure for partitioning of SW modules, (b) composition strategies for creating larger and complex SW modules, (c) quantification of interaction between SW modules, and (d) development of processes of mapping SW modules onto HW and (e) a novel decision procedure for determining the goodness of the mapping. A team has been formed consisting of WWTG's ultra-dependable systems experts, reconfigurable computing expertise from a leading university laboratory, and commercialization support from a Prime Contractor executing major satellite communications and sensor programs.A multi-phased commercialization program is defined for the insertion of robust reconfigurable computing (RC) technology in critical applications. Prior RC efforts focused on performance and failed to address dependability and hard real-time requirements. These attributes will be added in order to make RC technology "industrial strength" and merging the latest research results with design and production processes required to gain acceptance by identified and potential military and commercial contractors. A key element is WWTG's validated fault tolerant approach and newly developed partitioning technology targeted at specific military communications and sensor satellite, aircraft, and terrestrial applications defined by a leading Prime Contractor. Bandwidth performance improvements in satellite systems on the order of two orders of magnitude with reductions in size, weight, power consumption, and cost will greatly benefit military and commercial systems and acquisitions. A key component of the planned commercialization process is the tolerance to Single Event Upsets which enables the use of Commercial Off-The-Shelf (COTS) technology an insures the availability of the latest technology and low risk technology rollovers to maintain high performance levels along with low cost of development and ownership.

XCOM WIRELESS, INC. 1718 E. Ocean Blvd #4 Long Beach, CA 90802
Phone: PI: Topic#:	(562) 495-6090 Dr. Daniel J. Hyman AF 01-099 Selected for Award
Title:	MEMS for Space Communication Systems
Abstract:	XCom Wireless is developing a novel RF MEMS relay that can be incorporated into a wide variety of RF systems. The primary goal of this program is to develop these relays such that the relay actuator is encapsulated between an RF communications circuit and a protective package; the circuit and package are integral parts of the relay itself. Such a design will enable the superior RF performance typically found only in fully integrated devices yet retains the design and manufacturing flexibility inherent to discrete components. This proposal discusses the development strategy for combining the relay elements into a prototype radio as a transmit/receive switch. The ultimate goal is to further the maturity of the integration process such that advanced components such as agile filters, multi-band antennas, and phase shifters can be enabled by RF MEMS relays to achieve a high-performance low-cost space-based communications system.Commercialization of the technology to be developed in the present SBIR proposal represents a fundamental component of the XCom Wireless business strategy. Low-loss RF MEMS relays integrated with circuitry is a core technology of every XCom Wireless product, and sales revenue for all subsequent products may be attributed to the present initiative research. The estimated time to first product release is 18 months, with profitability possible in three years with sales estimates of 200,000 units at $10-30 each from defense industry customers. Production facilities require expansion by the end of the fifth year of operation to deliver high-volume products for consumer applications; this expansion is likely to require an initial public offering. A strategy of continuous patent development is instrumental to the growth and strength of XCom Wireless in the RF community, with two patents expected to result from the Phase II effort of this proposal.

MISSION RESEARCH CORP. 735 State Street Santa Barbara, CA 93101
Phone: PI: Topic#:	(505) 768-7677 Mr. Anthony Wilson AF 01-100 Selected for Award
Title:	Radiation Tolerant Field Programmable Analog Array
Abstract:	A proposal is made for the design, demonstration, and productization of a radiation tolerant field programmable analog array (RT-FPAA) suitable for space and terrestrial applications. Phase I activities include evaluation of the RT-FPAA architecture, design and evaluation of analog configurable-analog-block architecture (CAB). The proposal is based on two combining technologies: laser formed metallic connections that provide the basis for high quality programmable interconnects needed for programmable analog arrays; and a high performance fabrication process that provides the semiconductor technology for fabrication of the RT-FPAA.The RT-FPAA provides a low cost, quick turn-around, analog circuit solution to radiation tolerant signal conditioning microcircuits for use in satellite telemetry systems. The device will provide analog designers with capabilities currently employed by digital designers using FPGAs.

BJ INFORMATION TECHNOLOGIES LLC P.O. Box 42 Storrs, CT 06268
Phone: PI: Topic#:	(860) 429-1023 Dr. Bahram Javidi AF 01-101 Selected for Award
Title:	Fast Matching for Sensor Data Exploitation Using FPGA
Abstract:	This proposal addresses the need to improve automatic change detection and pattern recognition in surveillance/reconnaissance systems. In those applications, large amounts of data are generated and must be stored and processed for each scene, which makes real-time decision making a growing challenge. In the proposed Phase I project, we will study target matching algorithms which reduce the processing time. Another problem, which would be encountered in an operational imaging system, is the issue of signal processing hardware. The algorithms, to be studied in the proposed project, are insensitive to scale and rotation of the target in the image. The methods used in these algorithms are based on wavelet theory and genetic search paradigms. The hardware is a compact FPGA design with externally linked memory. In the Phase II project, we will fabricate a breadboard imaging system using the algorithms and the hardware design developed and evaluated in Phase I.FPGA based integrated sensor and signal processing for high-speed detection and identification of targets.

MTL SYSTEMS, INC. 3481 Dayton-Xenia Rd. Beavercreek, OH 45432
Phone: PI: Topic#:	(937) 426-3111 Mr. Richard K. Hill AF 01-101 Selected for Award
Title:	Associative Retrieval for Sensor Data Exploitation
Abstract:	MTL presents an efficient associative retrieval, storage, and dissemination technique for imagery and signal data in Imagery Intelligence (IMINT) and Electronic Intelligence (ELINT) applications. ARTEMIS employs an innovative approach to image and signal characterization, search, and retrieval, satisfying all solicitation requirements. ARTEMIS operates on both signals and imagery using the same, efficient functions - gaining operational efficiency over an approach using separate methods for different data types (images and signals). The Phase I Objectives are (1) Define Requirements, to lay the groundwork for testing feasibility and to produce a preliminary requirements specification, (2) Implement, Test, and Assess ARTEMIS Concepts, to evaluate, and demonstrate an ARTEMIS prototype, and determine functional feasibility, (3) Produce a Preliminary Design, to refine and supplement the prototype to become a preliminary design for Phase II, and (4) Assess Commercialization Potential, to determine ARTEMIS' market potential, and produce a preliminary commercialization (product) plan. The Phase I results will be (a) experimental test and analysis results forming the feasibility assessment, (b) a Phase II preliminary design, (c) an initial product plan, and (d) a prototype demonstration, to explicitly demonstrate ARTEMIS' feasibility to AFRL and users they support, such as ESC/SRG and the Information Exploitation Systems Program Office.ARTEMIS will adaptively select, retrieve, and disseminate only necessary data products. For military Intelligence, Surveillance, and Reconnaissance (ISR) operations, it will shorten response times to time-critical targets and rapidly changing battlefield situations. Commercial agricultural, medical, and architectural endeavors produce and utilize large volumes of imagery and signal products, including satellite-provided imagery. These enterprises will benefit from the ARTEMIS capability to rapidly and adaptively search, filter, and control dissemination of their products.

MODASCO, INC. 4303 Vineland Road,, Suite F-7 Orlando, FL 32811
Phone: PI: Topic#:	(904) 276-8296 Dr. John Woodring AF 01-102 Selected for Award
Title:	Architecture Specification and Validation Tools for Designing Command and Control (C2) Systems.
Abstract:	Modasco proposes an innovative, rule-based approach to prototyping advanced C2 systems. This technology specifies entities and entity relationships, such as hierarchy and association, in a C4ISR-compliant database and then specify and validate prototype C2 architectures using these entities as system building blocks. It is a significant improvement over the current way Colored Petri Nets (CPNs) are used, since it provides the designer with a palette of validated entities and entity relationships from which a system can be designed. It provides a simple way to build and use custom icons representing the validated entities, thus improving the visual, mnemonic and demonstrative appeal of the graphical system design. Since the entity definitions (icon, attributes, association and hierarchy rules) are declared in a database, the modification and extension of existing architecture palettes, and the development of new project-specific palettes, can be performed without modifying the design tools themselves. The proposed methodology interfaces with LEdit, a graphical editor developed by the Air Force. It extends LEdit's usefulness for prototyping C2 architectures by enforcing pre-declared operational and system constraints. This methodology has broad commercial appeal for systems re-engineering and will improve the way military worth is evaluated in a new generation of war-gaming models.Decrease the development time and cost for prototyping new systems. The proposed software tools are directly applicable to the design and analysis of commercial and military processes including information systems, healthcare, economic forecasting, software and hardware.

FRONTIER TECHNOLOGY, INC. 6785 Hollister Avenue Goleta, CA 93117
Phone: PI: Topic#:	(937) 429-3302 Mr. Sam Boykin AF 01-105 Selected for Award
Title:	Enabling Affordability in Science and Technology
Abstract:	The environment within the Department of Defense for acquiring weapon systems is rapidly changing. The defense procurement budget has fallen more that 50% from its peak, and DoD and the services are demanding more performance for less cost. Gone are the days when new systems could be developed and produced simply for reasons of greater payload, better reliability, more weapons on target, improved technology, etc. Now the benefits of performance improvements must be balanced against cost to arrive at a "best value" solution. In other words, the technology must be affordable. In the past, affordability was not often a priority for AFRL laboratory programs because the emphasis was on new technology, and the focus was strictly on performance. AFRL is attempting to measure and report return on investment (ROI) for S&T programs. Since a cost saving can't always be demonstrated for a new technology that provides previously unattainable military capability, innovative methods of measuring both investment and return, need to be developed. . This multi-phase SBIR develops the methodology and tools to evaluate financial returns on S&T investments. Phase I identifies and tests the ROI utility measures of merit. Phase II develops the prototype affordability tool set. DoD's acquisition community has a problem that is also common to many businesses: determine how to determine and then optimize return on investment (ROI) for science and technology. Decisions to invest in technologies that appear to have large performance potentials but do not deliver the desirable ROI, cost millions in lost opportunities. In their effort to develop and produce systems better, cheaper and faster, many large industries, aerospace and automotive, are moving to virtual digital design environments. The objective of this research project is to provide a computer tool that will enable AFRL, DoD, and industry to evaluate the affordability of an investment in science and technology by means of an ROI utility. An effective methodology/tool for evaluating financial returns on science and technology investments that will benefit the AFRL and can eventually be applied to the commercial environment The resulting tool has great potential for effective use in any industry

21ST CENTURY TECHNOLOGIES, INC. 8716 North Mopac Expressway Su Austin, TX 78759
Phone: PI: Topic#:	(512) 342-0010 Dr. Sherry Marcus AF 01-106 Selected for Award
Title:	ATO Link: A Link Analysis and Information Dominance Tool for ATO Planning
Abstract:	The objective of this Phase I effort is to produce "ATO Link", an operational link analysis prototype, that can predict and identify planning and re-planning conflicts during the ATO (Air Tasking Order) planning process. The analyst will have the capability to perform many "what if" scenarios and ATO Link will determine if there would be any future potential plan conflicts. ATO Link extends our current Phase II SBIR with Rome Labs in the area of link analysis for terrorist detection and complements our machine learning developments as a contractor for the Darpa Ultra*Log program. Such a capability has wide applicability and can be exploited not only by the logistics planner, but can be integrated into simulations for training purposes or be used as a tool in the Joint Battlespace Initiative (JBI). As noted within Joint Vision 2020, there is a great need within the military community for developing information dominant systems. Such systems provide users with "amplified knowledge" of the existing operational environment; link analysis is such an example of a tool. Commercial and military organizations spend billions of dollars in logistics per year. Information dominant tools that can accurately and effectively exploit the supply chain can be successfully inserted and exploited within this market.

CYCORP, INC. 3721 Executive Center Drive, Suite 100 Austin, TX 78731
Phone: PI: Topic#:	(512) 514-2985 Dr. Chip Masters AF 01-106 Selected for Award
Title:	Knowledge Based Data Monitoring for a Joint/Coalition Environment
Abstract:	Our objective is to determine the feasibility of, and optimal design for, the incorporation of a large body of formalized common sense knowledge into an information integration, filtering, and dissemination tool, in support of a multi-force coalition. With this substrate of knowledge, it is possible to identify relationships between data points, to understand the meaning of information across changing contexts and varied sources, and to recognize the significance of information across multiple contexts and users. Specific knowledge-based technologies to be applied include Cycorp's methods for representation of, and reasoning about, knowledge contexts, diverse data sources and their contents, data anomalies, and activities and plans. The application will support collaborative use of distributed information by integrating information from distributed sources, filtering information by significance, and distributing information to those for whom it is relevant.Intelligent information integration, filtering, and dissemination promises to reduce the need for human data filtering, enable users to benefit from distributed knowledge, and address the critical problem of getting the right information to the right person at the right time. Incorporation of a large body of formalized common sense knowledge enables understanding of, and reasoning about, both the context of information and the information itself. That understanding may well give information integration, filtering, and dissemination the depth and robustness needed to effectively support command decision-making, breaking through the barrier of information overload.

GRAMMATECH, INC. 317 N. Aurora Street Ithaca, NY 14850
Phone: PI: Topic#:	(607) 273-7340 Dr. Paul Anderson AF 01-106 Selected for Award
Title:	Detecting Malicious Code in Firmware
Abstract:	The problem of detecting malicious code has focused until now on techniques that search a program's surface structure representations to find locations where suspicious constructs occur. Such techniques are fundamentally weaker than methods that operate on representations that capture a program's deep semantics. We propose to study the feasibility and plan the development of tools for detecting malicious code that operate on a program's dependence graph. This representation captures a program's essential semantics and enables sophisticated semantics-based queries to be posed. Our plan is targeted at semi-automatic solutions for finding occurrences of malicious code in firmware. This work will build on our own dependence-graph based COTS product for program understanding named CodeSurfer. We will address the problem of generating dependence graphs from multiple machine languages using generic disassembly and decompilation techniques. We will plan the integration of these tools with CodeSurfer. We will develop queries for tell-tale signs of malicious code in firmware, and design a user-interface to help security analysts make the final determination of maliciousness. We will investigate methods for firmware editing to permit implementation of damage mitigation strategies. Finally we will develop a set of metrics that can be used to measure the success of our techniques.The proposed system will be of use in the semi-automatic detection of malicious code in firmware and other machine-code representations of programs. This system will be of benefit to companies wishing to show that their firmware implementations are secure, and to others wishing to understand machine-code level programs.

KNOWLEDGE BASED SYSTEMS, INC. 1408 University Drive East College Station, TX 77840
Phone: PI: Topic#:	(979) 260-5274 Dr. Dursun Delen AF 01-106 Selected for Award
Title:	Agent Based Toolkit for Integrated Planning and Execution of Coalition Operations (ATIP)
Abstract:	Changes in the political, economical, and technological environment (especially the effect of internet in bringing the world closer) is rapidly affecting the nature of military operations of U.S and NATO countries. These changes have lead to focus on coalition operations. "The process of plan development becomes uncertain when members of the planning staff are from different countries whose assets capabilities are not known, or whose culture does not allow certain missions to be carried out. Such differences can negatively impact the entire planning process. As the nature of engagement for U.S and allied forces change from a war emphasis to peace keeping emphasis, there is a need to develop infrastructure for planning and execution in coalition planning domains". The proposed Agent Based Toolkit for Integrated Planning and Execution of Coalition Operations (ATIP) effort addresses these issues by developing knowledge based assistance to coalition planning. The specific tasks addressed in Phase I are to develop : (1) ontology of coalition planning, (2) coalition plan representation framework and internet based methods to communicate and distribute coalition plans, (3) coalition plan templates, (4) agent based framework for execution monitor and re-planning, and (5) Coalition Plan Assistant (CPA) agents.ATIP will result in the development of innovative solutions to coalition planning. Immediate beneficiaries of ATIP technology will be DOD, NATO, and coalition planning community. In the commercial area, ATIP will be useful for any endeavor requiring collaborative plan development, execution, monitor and re-planning. Domains like virtual enterprises and B-to-B e-business domains will benefit from ATIP.

ORINCON CORP. 9363 Towne Centre Drive San Diego, CA 92121
Phone: PI: Topic#:	(858) 455-5530 Mr. Dale Klamer AF 01-106 Selected for Award
Title:	Basic Research for Level 2 Information Fusion
Abstract:	The proposed effort will address fundamental issues in the research and development of Level 2 fusion, namely, development of a solid mathematical foundation on which to build algorithms for situation refinement that includes organization and structure. We believe that the fundamental approach to fusion in Level 1 - that is, detection, prediction, association, hypothesis generation, hypothesis management, and update - is applicable to Level 2. Examining the key elements of Level 1 fusion, we can identify the parallel components of Level 2 fusion and evaluate the degree of development in the underlying fundamental theory. The area that provides the greatest hope for innovative research is in the development of metrics for working with discrete sets that represent Level 2 objects. Our research will be performed in the setting of discrete sets (Organization and Structure) and will be aimed at the development of metrics that measure the distance (or "nearness") between two discrete sets, the building of a theoretical foundation that will provide a setting in which to develop and evaluate metrics, and the application of these metrics to the Level 2 problems of detection, prediction, and association. Accomplishing these objectives will provide a basis for rapid development of Level 2 fusion.This work will lay the foundation for most of the future Level 2 fusion work. This includes the basic theory and the design, development, and implementation of algorithms for Level 2 detection and association. Metrics on Level 2 battlespace objects are essential for a foundation to build testing and evaluation testbeds that contain measures of performance and measures of effectiveness. With the advent of the Internet, huge amounts of data are being collected by virtually every business at an ever-increasing rate. We can envision that metrics developed under this work will provide new methods and approaches for both data mining and discovery of new relationships in data.

PHYSICAL OPTICS CORP. Photonic Systems Division, 20600 Gramercy Place, B Torrance, CA 90501
Phone: PI: Topic#:	(310) 530-7892 Dr. Eugene Levin AF 01-106 Selected for Award
Title:	Analytical Manifold Modeling for Dynamic Planning and Execution
Abstract:	The Air Force is soliciting innovative information technology for visualization, and manipulation of real-time multimedia data from complex battle field environments In response, Physical Optics Corporation (POC) proposes an innovative software package that relies on image-based, analytical manifold modeling (AMM) and a rendering algorithm that will allow unifying raster and vector image representation. The novel AMM technology is based on POC's proprietary algorithm, based on catastrophe theory which can derive three-dimensional (3-D) object models from two-dimensional (2-D) image projections. However, POC proposes to extend AMM's 3-D representation by adding another physical coordinate that differs from the regular geometrical coordinates in the image plane. This enhancement will permit POC's AMM algorithm to represent visual objects and terrain imagery as an analytic polynomial model. Also, it can create geometrically correct representations of the 3-D model when it is applied to image modeling. In Phase I, POC will: 1) develop the AMM algorithm for image-based modeling and rendering and 2) demonstrate the feasibility of the concept. In Phase II, it will demonstrate verifiable prototype software and refine and complete a mathematical model for verification in a close-to-real environment. Commercialization activities initiated in Phase I will be pursued further in Phases II and III.This technology will contribute to computer simulation and visualization, Internet-based virtual reality programs, computer games, and data mining. It can also be used for video conferencing, multimedia applications, and medical imaging.

SCS ENGINEERING, INC. 23430 Hawthorne Blvd., STE 240 Torrance, CA 90505
Phone: PI: Topic#:	(310) 373-4243 Mr. Jerry F. Shaw AF 01-106 Selected for Award
Title:	System Training and Rehearsal Suite (STRS)
Abstract:	SCS proposes to develop a System Training and Rehearsal Suite (STRS ��) that will support part task trainers through full mission rehearsal systems. The core thrust of STRS will be to develop nodes that will be used for Realtime Sensor-to-Shooter Operations training and rehearsals. The STRS will extend the Collaboration/Simulation/Visualization technologies currently being developed for AFRL under the Realtime Integrated Planner/Player (RIPP) SBIR. The STRS will allow any Microsoft Windows (Win32) based PC or workstation to be used within a building block system. The STRS will support commercial-off-the-shelf (COTS) computer systems, input devices and output devices. STRS will allow crews to fly/drive/operate mission system simulations in a standalone configuration or participate in distributed Multiple Engagement Simulation (MES) via DIS/HLA (either in collocated classrooms/facilities or distributed/deployed operating locations). Immediate multiple agency (e.g., USAF, USA, USN, SOF, USMC, USCG) applications for STRS include: mission rehearsal systems, mission execution systems, tactics, crew station/display trainers, UCAV mission trainers, indirect fire trainers, urban warfare trainers, low altitude ingress/egress rehearsal systems, mission system trainers, support and evaluation for dynamic planners, crew station part task trainers, a manned entity within a distributed simulation, an observer within a distributed simulations. The anticipated results of STRS will be a suite of tools for developing turnkey systems that will allow a crewmember to rehearse in realtime and non-realtime most if not all facets of a Sensor-to-Shooter Operations mission. The STRS system will be a highly deployable system based on commercial computer technologies. Core STRS technologies will be demonstrated to be applicable to all DoD user communities (e.g., USAF, USA, USN, SOF, USMC, USCG).

SIGMA SYSTEMS RESEARCH, INC. 9725 Aspen Hollow Way, #210 Fairfax, VA 22032
Phone: PI: Topic#:	(703) 582-0638 Dr. Jerzy Bala AF 01-106 Selected for Award
Title:	Exploration of Target Movements Through Evolutionary Computation and 3-D Visualization
Abstract:	The objective of this effort is to develop an integrated system for predicting opponents' strategic target movements in the battlespace and for displaying such predicted movements through an interactive 3-D visualization interface. The proposed prediction approach generates new movements based on past behaviors and application of inheritance mechanisms. Specifically, the approach is based on applications of Genetic Algorithms learning techniques to evolve new individuals in the population of movements. The methodology involved in this project encompasses recent innovations in Evolutionary Computation, as well as state-of-the-art techniques in 3-D Visualization. The implemented system is expected to yield robust performance in terms of higher automation of movement prediction. This system will greatly enhance strategic awareness and qualitative insights into opponents' state of knowledge.The proposed technology has applications to any commercial industry that evaluates data representing movements in a spatial and/or temporal space in order to determine the current state, analyze trends and forecast the future. Specifically, there are two main commercial application areas for this technology - Joint STAR for understanding of the ground moving targets in the battlefield and Geographical Information Systems (GIS) for transportation traffic prediction. This technology will also be applicable to all areas where generation of new realistic entities resembling already existing entities is required. These areas can range from the problem of generating new targets to the generation of new business operational scenarios.

STOTTLER HENKE ASSOC., INC. 1660 So. Amphlett Blvd., Suite 350 San Mateo, CA 94402
Phone: PI: Topic#:	(206) 545-3533 Dr. Tamitha Carpenter AF 01-106 Selected for Award
Title:	Mixed-initiative Defensive Information Warfare - A More Pragmatic Paradigm
Abstract:	We propose a new Defensive Information Warfare (DIW) paradigm that will effectively mitigate the risks to our nation's computer networks posed by a critical shortage of security savvy system administrators. We developed this approach in response to our recognition that information assurance tools will always remain a number of steps behind the craftiest information warriors, and therefore success in DIW will continue to depend on the human element. The proposed system, Athena, will enable the aggregation of critical DIW expertise and its exploitation by the less security proficient personnel that dominate the military's IT force. To accomplish this goal we draw on the technologies employed in the latest case-based problem resolution software as well as an extension of our own model-based "active evidential reasoning" system. Athena will offer guidance, founded in historic cases, to the user in collecting and appraising critical information and forming incident responses, while simultaneously accepting a variety of asynchronous inputs from the user. The prototype tool developed in our Phase I effort will prove the feasibility of mixed-initiative DIW and form the basis for a complete implementation of Athena in Phase II and its ultimate commercialization.Our mixed-initiative approach to computer security will be equally applicable to both military and commercial networks given the need to make optimal use of very limited system administrator and security officer resources.

TRIDENT SYSTEMS, INC. 10201 Lee Highway, Suite 300 Fairfax, VA 22030
Phone: PI: Topic#:	(703) 359-6226 Mr. Scott Thomas AF 01-106 Selected for Award
Title:	Component Active Service INterOperable (CASINO) Framework
Abstract:	Distributed computing systems have matured from simple client/server applications towards large complex systems. While computing processing and network bandwidth capabilities have dramatically improved in recent years, the design and implementation of complex systems remains difficult and expensive. Component software has emerged to address this issue. Several competing component technologies have been touted in the industry, including DCOM, CORBA, and JavaBeans. There are still many obstacles that must be overcome before the vision of a truly integrated component framework is realized. An interoperable framework that transcends these competing component standards is needed. Defense initiatives such as the Joint Battlespace Infosphere (JBI), have fundamental requirements of interoperability between diverse component systems. Trident proposes the application of XML-based ontologies, software agent and active network technologies to the problem space of interoperable component frameworks. An active network service, implemented using software agents that parse XML, will be injected into the component communication path. We plan to design a Component Active Service INterOperable (CASINO) Framework, compliant to the DII-COE. The CASINO framework provides a flexible, distributed infrastructure that enables interoperability between multiple component technologies, including DCOM, CORBA, and Java. To illustrate the feasibility of the CASINO framework, sample components will be developed and demonstrated. This work will generate the design of a DII-COE compliant framework, which enables interoperability between multiple component technologies. Products developed under the CASINO framework can provide for seamless, theater-wide interoperation among the various applications that planners and operators utilize. This capability will reduce the time and cost required to evaluate intelligence data and enable COTS technology to leveraged for data fusion applications.

TRIDENT SYSTEMS, INC. 10201 Lee Highway, Suite 300 Fairfax, VA 22030
Phone: PI: Topic#:	(703) 359-6226 Mr. Scott Thomas AF 01-106 Selected for Award
Title:	DICE Archive System (DAS)
Abstract:	Intelligence analysts face increasingly significant challenges in the timely acquisition, correlation and analysis of intelligence information. Recent information technology advances have resulted in explosive growth in the volume and rate of intelligence data pushed to the analyst. Recent military initiatives, including the Consistent Battlespace Picture (CBP) and the Joint Battlespace Infosphere (JBI), highlight the intelligence community's awareness of these issues. Work remains to be done for building the JBI and leveraging current systems, including CBP. There is a great need for secure collaboration between disjoint sets of users. This multimedia data is critical to providing a complete picture of the battlespace so that decision-makers and warriors alike have the right information at the right time. By capturing collaboration data, and applying appropriate metadata, filters may be used to automatically communicate information across security boundaries. Trident proposes the development of a robust, secure multimedia recording architecture based on the Distributed Intelligence Collaboration Environment (DICE). DICE, which is part of CBP, has the capability to record audio, video, and whiteboard data. The DICE Archive System (DAS) will support standard formats and utilize XML technology to identify intelligence products. DAS will significantly improve the Global Awareness capability for the DoD and Intelligence Communities. This work will develop a DII-COE compliant multimedia archive system, compatible with existing AFRL programs, including Broadsword, CBP, and JBI. DAS will enable secure collaboration by capturing multimedia data and applying XML-based tags. Automatic filters may be used to communicate information across security boundaries. Moreover, by associating XML metadata with the intelligence products, new and innovative content-based retrieval mechanisms may be developed. The work proposed will provide the capability to reduce the time and cost required to evaluate intelligence data and improve the Global Awareness capability for the DoD and Intelligence Communities.

CHARLES RIVER ANALYTICS, INC. 725 Concord Avenue Cambridge, MA 02138
Phone: PI: Topic#:	(617) 491-3474 Dr. Subrata K. Das AF 01-107 Selected for Award
Title:	Situation Assessment Fuselet to Aggregate Retrieved Information (SAFARI)
Abstract:	We propose to develop a Situation Assessment Fuselet to Aggregate Retrieved Information (SAFARI) obtained from the Joint Battlespace Infosphere (JBI) repositories to support the development of mission relevant knowledge via Bayesian Belief Network (BN) technology. A BN can be thought of as a graphical program script representing causal relationships among various battlefield concepts represented as nodes to which observed evidence can be posted. Depending on the battlefield situation, a BN is constructed from a library of networks to instantiate SAFARI. An if-then type of speculative analysis on the constructed BN identifies relevant information that needs to be retrieved and posted to nodes for assessing the situation. An inferencing process on the same network performs the aggregation of posted evidence to infer high-level battlefield situations. BN technology offers several advantages, including its graphical approach to situation assessment modeling and handling of uncertainty consistent with probability semantics. At Charles River Analytics we have been successfully applying BN technology for situation assessment tasks in a number of domains, including Major Theater of War (MTW) scenarios, Theater Missile Defense (TMD) domains, and air combat engagements. We believe that SAFARI will significantly enhance the JBI's capability of transforming data into mission relevant knowledge.Commercial applications of the proposed situation assessment fuselet concept based on belief network technology exist for a wide variety of contexts characterized by high rates of information flow and decision-making under uncertainty. Such application areas include operation centers for complex process control (e.g., nuclear power plants, water resource distribution), and rail and air traffic management centers. Vertical applications for these markets would significantly enhance fault diagnosis, improving effectiveness and safety in a number of life-critical applications.

ORIELLE, LLC PO Box 8922 Moscow, ID 83843
Phone: PI: Topic#:	(208) 892-0667 Mr. Peter H. Mills AF 01-107 Selected for Award
Title:	An Extensible Framework for Rapid Fuselet Composition
Abstract:	We propose to develop scripting language enhancements to enable the rapid synthesis of publish-subscribe fuselets through a unified framework for subscription and resource discovery based on XPath and XQL extensions, to design and prototype its implementation in an extensible manner by mapping onto existing interpreter and runtime infrastructures using a combination of dynamic source-to-source transformation and underlying library extensions, and to design an interactive development environment for semi-automatic fuselet generation and monitored execution. The provision of semantically conservative extensions which realize advanced query and discovery capabilities is, we posit, vital to the effective integration of evolving COTS scripting and XML technologies into the next generation of battlefield information systems, and will have broad applicability in the larger arenas of document retrieval and networked computation.A scripting language for the rapid assembly of data fusion processes whose query and discovery facilities are XML based will prove of great utility to the defense sector which is rapidly adopting XML as a military information standard in many large-scale projects. The program transformation and development environment technologies would have dual use in the commercial sector.

CHARLES RIVER ANALYTICS, INC. 725 Concord Avenue Cambridge, MA 02138
Phone: PI: Topic#:	(617) 491-3474 Dr. Subrata K. Das AF 01-108 Selected for Award
Title:	Generic User-friendly Integrated Development Environment (GUIDE)
Abstract:	The Joint Battlefield Infosphere (JBI) is a combat information management system that provides individual users with the right information at the right time during crisis and conflict. But the information needed by an individual commander or analyst cannot be fully anticipated beforehand based only on functional responsibilities, as it also depends on the dynamically changing state of the mission at hand. What is required is an environment that allows users to specify their time-critical context-dependent informational needs, and then support the rapid configuration of tailored agents to serve those needs. We propose to design and implement such a Generic User-friendly Integrated Development Environment (GUIDE) for creating intelligent software agents "on the fly" to be used in the JBI. The visual interface of GUIDE accepts high-level declarative specifications and then supports the graphic construction of agents from a library of components that cover key battlefield information management tasks, including: retrieval and fusion of data from various sources, filtering to avoid information overloading, high-level situation assessment, and inter-agent communication.The proposed integrated development environment will enable system developers to specify, design, implement, and validate agent-based systems with a broad range of functionality, and with enhanced reusability and significantly reduced development resources as compared with stovepipe code development practices now in use. Commercial applications of agents produced by GUIDE exist for a wide variety of contexts characterized by frequent information retrieval (e.g. Internet shopping), high rates of information flow (e.g. stock market), and decision-making under uncertainty (e.g. complex process control centers).

CAPRARO TECHNOLOGIES, INC. 311 Turner Street Suite 410 Utica, NY 13501
Phone: PI: Topic#:	(315) 733-0854 Dr. Gerard T. Capraro AF 01-109 Selected for Award
Title:	Multicast Ontology-Based Object Repository Derivation/Dissemination for the Joint Battlespace Infosp
Abstract:	A research effort to define a distributed ontology infrastructure for the derivation and dissemination of data, knowledge and information for the Joint Battlespace Infosphere (JBI) Publish and Subscribe paradigm is proposed. The design will emphasize the client side of the JBI architecture where the users' computing device can vary substantially in bandwidth, processing capability, screen size, and connection type. Today's Internet user is not limited to a single connection. They can connect with the net at any time using a wide variety of devices. Our emphasis is on designing a JBI infrastructure that will intelligently support the efficient rapid access and dissemination of distributed knowledge base repositories to a client independent of computing device or connection. We will use the appropriate specifications and standards such as those of the World Wide Web Consortium (W3C) and leverage the numerous research efforts funded by the USAF and DARPA. Our goal is to design and develop an infrastructure that will efficiently and rapidly provide data, knowledge and information to a dynamic user.The results of this effort will benefit dynamic decision makers throughout the military by providing them accurate, secure, and timely information. It will present the information in a manner that will be compatible with a dynamic user profile, the type of computing device used, the type of connection available, and their physical relationship to a command center. Commercial applications include those organizations with widely distributed resources and people, such as the airline industry, companies with large sales forces distributed throughout the world, and news agencies.

FETCH TECHNOLOGIES 4676 Admiralty Way, 10th floor Marina del Rey, CA 90292
Phone: PI: Topic#:	(310) 448-8275 Dr. Steven Minton AF 01-109 Selected for Award
Title:	Information Agents for Knowledge Integration and Dissemination in the JBI
Abstract:	A critical part of the vision described in the SAB report on Building the Joint Battlespace Infosphere are the tools that allow users of the JBI to construct their own new information repositories, possibly in the form of "fuselets", re-using existing knowledge and contributing their own. These integrated sources of knowledge will operate in the "publish and subscribe" environment envisioned for the JBI. The work proposed will ultimately provide end-users with the ability to rapidly specify an information integration/management task, picking from an ontology of information sources. A task can then be given to an agent that will efficiently perform it either on demand or repeatedly at some specified interval. The tasks we will support are complex and varied. They include, for example, retrieving information from one or more data sources, fusing information from these sources, filtering and summarizing information, publishing new composite data sources or briefings, and notifying users when prespecified conditions hold.Successful completion of the proposed Phase I effort will conclusively establish the feasibility of extending our Theseus approach-previously proven in the context of Web information sources-to the building of information integration and dissemination plans within the JBI. Furthermore, it will start mapping out an ontology of information sources, which will ultimately serve as a repository of sources that Theseus will be able to utilize to construct new knowledge. All these taken together will contribute to the development of successful commercial tools for rapidly accessing and disseminating information in distributed knowledge-based repositories.

TEKNOWLEDGE CORP. 1810 Embarcadero Rd Palo Alto, CA 94303
Phone: PI: Topic#:	(650) 424-0500 Mr. Adam Pease AF 01-109 Selected for Award
Title:	JBI Ontology Services (JBI-OS)
Abstract:	We will create a JBI ontology and ontology management, authoring, translation and distribution system that will serve both to make DoD software components more robust and to make integration possible at the semantic level. We will deliver: (1) A large, standards-based, open-source, upper ontology from the IEEE Standard Upper Ontology effort (2) A collaborative ontology authoring system from the DARPA RKF program (3) Knowledge compilation technology from the Army ICCES, CIA ATT, and DARPA EndState jumpstart efforts (4) Inference technology from a CIA ATT program (5) Search technology from the DARPA DAML program (6) Ontology browsing, editing and translation to XML from the DARPA IA&S program. Research and applications in computer science are creating the need for precise definitions of the concepts that make up our world. Web searching is handicapped by the limitations of specifying search criteria in terms of keywords rather than concepts. Automated natural language understanding, both oral and written, is severely limited by the ambiguity of language. Software engineering is limited by the need for engineers to define concepts to model the world. Integrating the meaning (or semantics) of databases and programs is crucial for creating software that is reliable and scalable. The use of ontologies to specify semantics is emerging as a promising technique for software integration. We propose an approach in which we define all the concepts formally in first order logic. In this way, we ensure that there is a truly shared definition. We also will build on a large common sense ontology that already has a huge number of fundamental distinctions. This helps guard against the need to reorganize the representation when assumptions change. Our commercialization strategy is founded on an open-source approach for base technology development and dissemination and development of commercial applications on top of the open-source base. The impact of our technology transition opportunities will be significant. In particular, Teknowledge has two major e-commerce business areas that these tools will support which include our TekPortal(tm) financial information portal and our retail SalesAssociate(tm) product.

INFORMATION EXTRACTION & TRANSPORT 1911 N. Ft. Myer Drive, Suite 600 Arlington, VA 22209
Phone: PI: Topic#:	(703) 841-3500 Dr. Suzanne Mahoney AF 01-111 Selected for Award
Title:	Mixed Resolution Modeling Issues for the Battlespace InfoSphere
Abstract:	IET proposes to develop a decision theoretic design for Mixed-Resolution Modeling. The key concept is to treat a parameter produced by one model/simulation as evidence for the actual value of a parameter required by a second model/simulation. IET will investigate the feasibility of constructing an influence diagram that suggests an appropriate value for a parameter given information about the models/simulations. To preserve stochastic fidelity and support real-time and abstracted simulations, IET proposes a random variable representation for parameters. To facilitate parameter matching among applications running at different levels of resolution and how much evidential weight to give a parameter, IET proposes to design a knowledge representation for metadata associated with a parameter. The metadata will be incorporated into the constructed influence diagram and will include knowledge about the parameter's validity and the context under which it was derived. To support reuse of parameter transformation knowledge, IET proposes to investigate the utility of a knowledge base of Bayesian network fragments that perform parameter credibility assessments, parameter conversions and parameter selection. From such fragments, one could automatically construct a parameter-specific influence diagram that infers a value/distribution for the parameter. IET will investigate relevant commercial and DoD standards and requirements of the JBI.The market need for mixed-resolution modeling is well documented for the DoD. Just a few examples of where IET envisions our solution to mixed-resolution modeling to be of use include: i) clearly within the community that will be taking advantage of the JBI, ii) in the modeling and simulation functionality provided with the Global Command and Control System (GCCS) and the Global Combat Support System (GCSS), and iii) in supply and logistics entities within the DoD (e.g., US Transportation Command). IET has also identified several non-DoD markets within the civilian and commercial communities, these include: i) Economic Modeling - Complex economic forecasting performed by the government, private industry and universities clearly has a requirement for mixed-resolution modeling, ii) Ecological Modeling - Another area that can clearly benefit from the integration of mixed-resolution modeling techniques is ecological forecasting and analysis, and iii) Earth Science Modeling - Research organizations and universities interested in combining information from multiple data sources and simulations for modeling planetary phenomena will benefit from technology that supports mixed-resolution modeling.

WINDMILL INTERNATIONAL, INC. 2 Robinson Road Nashua, NH 03060
Phone: PI: Topic#:	(603) 888-5502 Mr. David W. Martin AF 01-115 Selected for Award
Title:	Automated Test Program Assessment System
Abstract:	This Phase I effort will establish the feasibility of capturing the available knowledge base of test expertise, outlining the logical workflow of the assessment process, and then capturing that knowledge in an automated tool. Windmill International has teamed with Ball Aerospace & Technologies Corp to provide the software tools and knowhow to capture the expert process outlined as part of the research.The results of this research effort will be a feasible initial concept for developing a Test Program Assessment tool that is user friendly and will allow lesser experienced test and acquisition professionals to take advantage of an expert assessment of their test program. This approach - of modeling and capturing an expert assessment capability can be applied in many ways to similar situations within the commercial environment. Direct application to commercial test programs is one example, but any commercial work process can be captured, assessed, or optimized as a result of developing such a robust set of tools.

NATURAL SELECTION, INC. 3333 N. Torrey Pines Ct., Suite 200 La Jolla, CA 92037
Phone: PI: Topic#:	(858) 455-6449 Dr. Lawrence J. Fogel AF 01-116 Selected for Award
Title:	An Intelligent Tool for Dynamic Situation Assessment and Prediction (DSAP)
Abstract:	Innovative technology is required to build a tool for dynamic situation assessment and prediction (DSAP). Human behavior in combat is often degraded by the stress of combat and other uncertainties. The decision maker must select the optimum course of action in light of decisions that have already been made as well as projected new factors. Unfortunately, this process is subject to considerable human error. A tool for reliably investigating alternative courses of action on the fly could lead to significant improvements in combat mission planning and replanning. Natural Selection, Inc. proposes an innovative research and development plan that involves multiresolution modeling, optimization, simulation, agent-based evolutionary algorithms, and a Valuated State Space(TM) Approach for quantifying and optimizing courses of action in faster than real time.The benefits of a successful development of a DSAP tool include better command and control, mission planning and replanning. Similar issues arise in commercial activities, including air traffic and freeway control, as well as business strategy.

SYNERGIA LLC 2400 Broadway, Suite 203 Redwood City, CA 94063
Phone: PI: Topic#:	(650) 569-4999 Dr. Michael Fehling AF 01-116 Selected for Award
Title:	Dynamic Situation Assessment and Prediction: Risk-Advised Planning
Abstract:	The complexity and tempo of modern conflict, and the severity of its possible results, prevent us from having a 'perfect plan' prior to execution. At the same time, information resources are constantly delivering information on adversaries and on execution results. Therefore, real-time, dynamic, in situ planning and replanning are required to exploit changing information and conditions. Our approach synthesizes methods and technology for planning, human (cognitive and social) system modeling, and decision/risk analysis. Simulation experiments (what-if studies) produce predictions of the evolution of situations, and each COA's associated performance. We use (normative) decision modeling to: assess risk, identify COA flaws, diagnose causal sources of flaws, detect alert conditions, and efficiently summarize explanations of risk assessments. Sensitivity and other calculations on the decision model recommend opportunities for COA improvement, both to exploit opportunities and repair unwarranted risks. Predictions and assessments combine in the decision model to focus and bracket analysis. Focusing aids and multi-resolution representation and analysis methods underwrite faster-than-real-time performance. Synergia has produced a concept of operations, and methods and technologies for modeling, simulation, and organizational risk analysis to support planning. We propose to develop and refine them for dynamic situation assessment and prediction. Synergia will create the capability to produce robust plans - plans that evolve and that tend with high probability to capture or preserve most of the value at stake and mitigate potential for major losses. This will markedly improve our ability to fight modern wars, and to produce methods and technologies for planning and critical business decision-making.

ODYSSEY RESEARCH ASSOC., INC. 33 Thornwood Drive, Suite 500 Ithaca, NY 14850
Phone: PI: Topic#:	(607) 257-1975 Dr. Frank Adelstein AF 01-119 Selected for Award
Title:	Mobile Platforms to Support Network Forensics
Abstract:	In a large computer network, a sophisticated, coordinated attack can have a devastating impact. To thwart the effectiveness of such an attack, investigators and administrators must be able to quickly understand what resources were affected and how they were affected. Complicating this task is the fact that few large facilities, either commercial or military, have sufficient expert personnel to physically examine each network segment that was attacked, as often these networks will be hundreds, if not thousands, of miles apart. We propose to create mobile forensic platforms (MFPs) as a tool to aid the investigators with the forensic task. MFPs are computers that can be quickly deployed on any network to perform remote forensic investigation with very high assurance security. The MFPs will contain a number of extensible forensic tools to allow an investigator to quickly and securely examine network resources remotely.The anticipated benefit is the ability to quickly respond to coordinated computer attacks. Because of the limited number of expert personnel that can perform network forensics in any organization, mobile platforms for forensics will provide an edge in defending against such attacks by giving investigators direct, low-level access to many geographically diverse networks. This increases the effectiveness of the experts by allowing them to conduct investigations without requiring them to travel to the sites, which in turn creates a stronger defense against coordinated attacks. The mobile platforms provide remote access without further risk to the security of the installation (and in some cases, allow them to conduct an investigation even when internal network connectivity is unavailable). There is a direct path for commercialization, since commercial organizations must face the same threat of coordinated attacks with limited personnel and will benefit from this technology.

BROWNE TECHNOLOGY, INC. 8395 Greenwood Dr. Longmont, CO 80503
Phone: PI: Topic#:	(615) 377-9406 Mr. James Browne AF 01-121 Awarded: 04APR01
Title:	Combined Thermally and Electrically Conductive Adhesives
Abstract:	We are proposing the development of adhesives that will be capable of conducting heat and electricity at levels significantly above currently available systems while offering improved processability. A novel thermoplastic/epoxy hybrid paste adhesive will use an advanced formulation approach to achieve unusually high conductive filler and thermoplastic loadings while still maintaining a low viscosity. It will have a thermal conductivity of more than 15 W/mK combined with an electrical resistivity of less than 40 microhm-cm. This is a combined performance better than the separate film adhesives currently used for the F-22 sub-array assembly. Further improvement of the electrical or thermal properties will be possible with additional development. A high thermoplastic content will allow rework and will provide unusual toughness to resist thermal cycling failure. The advanced formulation approach to both high filler and thermoplastic content will still allow a material that flows like current pastes, thus allowing the productivity gains of automatic dispensing. In order to provide a technology backup and process alternative, we will also develop an epoxy film with both a thermal conductivity (>40 W/mK) and an electrical resistivity (<20 microhm-cm) better than solder. This z-axis film is the next generation of technology of our z-axis thermally conductive adhesive that has been developed for the BMDO/USAF. This will eliminate the need for separate adhesives for the F-22 sub-array assembly in areas of very high thermal or electrical transport across an adhesive bond line and will open many applications for solder replacement. The best thermally conductive adhesives are diamond filled and have a thermal conductivity of 10-12 W/mK with very high electrical resistance. The highest electrically conductive adhesives have a resistance of 100 to 500 microhm-cm and a thermal conductivity of 2-5 W/mK. Our proposed automatic dispensable paste adhesive will initially provide up to 20 W/mK thermal conductivity together with less than 40 microhm-cm electrical resistivity. A flowable paste adhesive with these much higher conductivities will open up many high performance electronic assembly applications due to the productivity improvements created by automated processing. The proposed z-axis film adhesive will be able to out perform solder in both thermal and electrical conductivity while requiring a sharply lower processing temperature. Such significant performance enhancement will find application in a variety of electronic packaging products and processes to reduce the yield loss caused by the high processing temperature of solder.

TEXAS RESEARCH INSTITUTE AUSTIN, INC. 9063 Bee Caves Road Austin, TX 78733
Phone: PI: Topic#:	(512) 263-2101 Dr. George P. Hanson AF 01-121 Awarded: 09MAY01
Title:	Thermally and Electrically Conductive Adhesives for the F-22 Subarray Assembly
Abstract:	The issue to be addressed by the proposed effort is adhesive failure in critical components of the Air Force's F-22 radar system. The high density of these subarrays creates very demanding thermal swings, which challenge the integrity of the adhesives being used currently. Failures are occurring at unacceptably high rates. TRI/Austin, working with Auburn University, proposes to correct this problem by developing an adhesive that exhibits very high thermal stability that is filled with a material that exhibits both high thermal and high electrical conductivity. We will use a combination of theoretical and practical modeling to predict and enhance adhesive performance. Systematic experimental designs will be used to cost effectively obtain an optimum composition. This will be based upon iterative tests of adhesive strength and durability after exposure to extreme thermal cycles. At the same time Auburn University will measure thermal conductivity and design and construct a laminated, multi-material model to mimic thermal performance in the subarray. A number of instrumental methods will be used at both facilities including microscopy, infrared spectroscopy, and differential scanning calorimetry to characterize adhesive failure modes. We believe the proposed approach and assembled research team will to solve the F-22's radar problem quickly and efficiently.The immediate benefit of this development work to the Air Force will be the delivery of a high performance adhesive that eliminates bonding failures in the F-22 radar subarrays. The electronics, telecommunications and aerospace industries all have need for adhesives that exhibit performance beyond the best epoxies, urethanes and acrylics. Demanding swings in temperature in space can cause premature failures in critical or expensive systems. At the very least, they can become a limiting factor in the life of a satellite, transport vehicle or space station. The ability to tailor adhesives for significant improvements in thermal or electrical conductivity, or both, takes the adhesive beyond just a structural material. It now becomes integral to circuit performance and heat dissipation. The state of the art in microprocessor spped and density is limited by the issue of heat removal. If this can be adequately addressed, computing power will continue to improve at reduced cost.

FARADAY TECHNOLOGY, INC. 315 Huls Drive Clayton, OH 45315
Phone: PI: Topic#:	(937) 836-7749 Dr. Maria Inman AF 01-122 Awarded: 01MAY01
Title:	Prediction of Corrosion Protection System Aging by Theory Based Data Mining
Abstract:	Corrosion damage to aging aircraft is the highest maintenance cost for the U.S. Air Force, and decreases the time that aircraft are available for missions. In order to continue using the aircraft beyond their design life, while staying within the budget constraints of the U.S. Air Force, maintenance costs must be decreased. This requires the capability to predict both degradation of the corrosion protection systems, as well as subsequent corrosion damage to aircraft structures, so that early action can be taken to avoid damage. This Phase I SBIR program address the critical need for prediction of corrosion protection system aging and corrosion damage. The proposed approach is to enhance existing theoretical models for protection system breakdown and corrosion mechanisms, with sophisticated data mining processes to validate, refine or change those models. In Phase I, we will demonstrate the power of data mining to model one aircraft component and its associated corrosion protection system, specifically a coated lap splice joint, and validate the models with limited experimental data. In Phase II, we would extend this approach to a wide range of protection systems and structures on aircraft, and develop broad models based on a combination of theory and data mining.The anticipated results of the Phase I & II efforts are the development and commercialization of a model that predicts the lifetime and performance of a corrosion protection system for aging aircraft components, and the onset and propagation of corrosion resulting from coating degradation, for both military and commercial applications.

S & K TECHNOLOGIES, INC. 53347 US Highway 93 Ste T Ronan, MT 59864
Phone: PI: Topic#:	(937) 229-4717 Dr. Jill S. Ullett AF 01-122 Awarded: 13APR01
Title:	Corrosion Prediction: Assessing the Effect of Corrosion Protection System Aging
Abstract:	Aircraft coatings are complex systems consisting of metal/conversioncoat-primer interface, primer coat, and topcoat. Degradation is caused by synergistic mechanical and chemical/environmental effects. This phase I proposal focuses on modeling the chemical degradation of the coating system due to UV and water exposure only. Multi-spectral analysis and electrochemical impedance techniques will be used to follow chemical changes in the system with exposure level and time. An experimental plan has been devised whereby the degradation of each component of the coating system can be determined. Based on the experimental findings,S&K Technologies existing corrosion prediction life service model will be enhanced to include degradation of the coating system as a function of time and basing.A test methodology for evaluation of coating systems for aluminum and a coating life prediction tool will result from this Phase I effort.

GENERAL LASERTRONICS 830 Jury Ct, Suite 5 San Jose, CA 95112
Phone: PI: Topic#:	(408) 947-1181 Mr. James Thomas AF 01-123 Awarded: 01MAY01
Title:	Removal Tools and Process for LO Materials
Abstract:	General Lasertronics proposes to adapt its Model A600 Laser Coating Remover to improve the efficiency of material removal and repair for Low Observable coatings and finishes. The Model A600 is field deployable and has a portable workhead with waste capture, laser safety sensors, and a explosion safe design. The effort will define laser operating conditions and power/efficiency upgrades for F-117A repair.In addition to removal/repair of LO materials, the technology is applicable to removal of standard paints, to cleaning and decontaminination of various metals, and to removal of sealant compounds.

UNCOPIERS, INC. 6923 Redbud Drive Manhattan, KS 66503
Phone: PI: Topic#:	(785) 293-4917 Dr. Sameer I. Madanshetty AF 01-123 Awarded: 02MAY01
Title:	Removal Tools and Process for LO Materials
Abstract:	This phase-I effort seeks to demonstrate the feasibility of developing a coating removal method based on a novel, environmentally-friendly (chemical-free and energy efficient) technology known as Acoustic Coaxing Induced Microcavitation (ACIM). In ACIM-based technologies silent sound is used to create intense energy points (imploding microbubbles) on wetted surfaces. In this project, the precise point-of-use energetics of ACIM-powered microbubbles are applied to the important problem of removing radar absorbing materials (RAM) from aircraft surfaces.This phase-I project will lead to the development of an ACIM activated handheld sonifier for controlled in situ RAM decoating with no damage to the underlying metal/composite substrates. Beyond the RAM removal task, this ACIM-powered tool will function as a universal decoater of broad applicability. ACIM technology uses only silent sound and clean water. ACIM technology has broad applications to semiconductor processing, thin film metrology, and paper recycling.

FOSTER-MILLER, INC. 350 Second Ave. Waltham, MA 02451
Phone: PI: Topic#:	(781) 684-4119 Ms. Carolyn Westmark AF 01-124 Awarded: 02MAY01
Title:	Ice Phobic Coatings for Low Observable (LO) Aircraft
Abstract:	In this Phase I program, Foster-Miller will develop and evaluate coatings that can prevent ice from forming or reduce the adhesion strength of ice on the surface of low observable (LO) aircraft. Foster-Miller will examine coatings that self-organize on the aircraft surface to provide a hydrophilic moiety to bond to the substrate surface and a hydrophobic moiety to create a high-energy surface that is resistant to ice adhesion. In addition, Foster-Miller will investigate the use of novel "active icephobic" coatings that can absorb and release freezing point depressant compounds. These coatings will melt accreted ice at the coating/ice interface, thus eliminating the adhesion of the ice to the surface. Coatings will be tested for hydrophobicity, adhesion to the substrate, hardness, and low observable properties. A screening test for ice adhesion will also be performed on each coating. (P-01332) Successful implementation of this technology will result in an increase in flight safety and reduction of engine damage risk from ingestion of ice on low observable aircraft.

MICROPHASE COATINGS, INC. 170 Donmoor Ct Garner, NC 27529
Phone: PI: Topic#:	(919) 662-0401 Dr. William Simendinger AF 01-124 Awarded: 10MAY01
Title:	Ice Phobic Materials
Abstract:	After four years of research, MicroPhase Coatings has invented a breakthrough silicone-silicate technology. Preliminary tests indicate that the coating is ice-phobic and meets requirements for aviation use. During Phase I we prove: (a) feasibility of using the coating to prevent ice buildup in B-2 engine inlets, and (b) compatibility with B-2 systems and Low Observable materials. During Phase I we refine the technology and select the optimum formulation. We conduct LO compatibility assessments; AFM/SEM Morphology studies; Ice Adhesion measurements; GC/FTIR analysis of High Temperature Gases; and Contact Angle Measurements. We conclude with Icing Wind Tunnel tests, Sand Abrasion, and Water Erosion tests at an internationally recognized aviation icing testing facility. This project will be conducted by a technical and management team that is accomplished in the development and introduction of high technology into the aerospace marketplace. Internal capabilities are augmented by internationally recognized expert consultants, companies, and academia.Anticipated benefits and commercial applications are immense. They are listed in increasing order of potential impact: (1) suitable for eliminating engine ice damage in the B-2; (2) suitable in other engine inlets; (3) supplement to active airframe de-icing systems, allowing them to be smaller, lighter weight, and use less power; (4) a stand-alone passive anti-icing system. Commercial applications of this potentially breakthrough technology also extend to non-aircraft surfaces where ice can be a problem, such as antennas and power transmission lines and equipment. Our partners for follow-on phases include aircraft manufacturers, de-icing system vendors, FAA, NASA and DoD. Upon successful Phase I, private and federal funding for follow-on R&D are assured.

ACOUSTIC IDEAS, INC. 84 Barnard Avenue, Suite 2 Watertown, MA 02472
Phone: PI: Topic#:	(800) 757-5028 Dr. Vincent Lupien AF 01-125 Awarded: 20APR01
Title:	Phased Array Ultrasonic Inspection of Fastener Holes in Thick Multiple-Layer Structures
Abstract:	Budgetary constraints on defense spending have highlighted the importance of programs aimed at extending the service life of aging aircraft. Nondestructive inspection is a key component of such programs. One important capability is the detection of cracking and corrosion around fastener holes. Phased array ultrasonics offer a novel and powerful solution. They can steer an ultrasonic beam at various angles around the hole, allowing a range of skin thicknesses and fastener diameters to be inspected without mechanical adjustments. Complete circumferential scans can be performed, in some cases without any physical motion of the probe. The added flexibility of examining flaws at a whole range of angles simultaneously leads to a higher probability of detection. The elimination of some or all physical motion reduces weight, size and complexity. The feasibility of detecting first layer corner cracks on the faying surface using phased arrays has been demonstrated in a prior USAF program. Similar technology could be applied to the detection of cracks in multiple layer structures provided sealant exists between the layers to ensure coupling. This proposal outlines our approach for overcoming the technical hurdles of applying phased arrays to thick, multiple layer structures.It is anticipated that technology developed under this SBIR will have direct benefits for United States Air Force Aging Aircraft Programs by allowing safe, rapid and effective nondestructive inspection of fastener holes in thick, multiple layer structures and that such technology, if proven successul, would be acquired by the DoD. As the cost of the technology decreases, it is believed that commercial carriers may also develop an interest.

ALBANY INSTRUMENTS, INC. 1500 Princeton Avenue Charlotte, NC 28209
Phone: PI: Topic#:	(704) 332-3280 Mr. Teodor Dogaru AF 01-125 Awarded: 13APR01
Title:	Eddy current detection of cracks within the bore of installed Taper Lock fastener
Abstract:	It is proposed to develop novel eddy current probes based on spin dependent tunneling (SDT) magnetoresistive (MR) sensors to enhance the probability of detection of cracks within the bore of installed Taper Lok fasteners. Preliminary results show that the use of shaped excitation coils, together with extremely sensitive SDT sensors properly positioned above the structure under inspection, provides a significant improvement for deep crack detection around fasteners. By using specific coil geometry, the eddy current density can be focused on the circular edge of the fastener hole, where cracks can initiate. Consequently, the perturbation of the eddy current flow due to the presence of the crack is greatly enhanced. The proposed rotating self-nulling probe does not require either additional ferromagnetic flux focusing lenses, or compensation of the excitation field, as in prior art. Within this phase I project, different coil geometries and location of the sensor relative to this coil will be compared and the performance limitations of each design will be studied. A simple manual scanning system will also be developed for fast inspection of holes.The novel eddy current probes will provide an effective tool for detecting small cracks within thick wing splice joint structures, without the need to remove the Taper Lok fastener. It is envisaged that the proposed approach will outperform current state-of-the-art eddy current techniques used to address this difficult problem, in terms of both size and depth of defects that can be reliably detected around the fastener holes. Both military and commercial aircraft industries will directly benefit from the development of these novel probes.

SYNTERIALS, INC. 318 Victory Drive Herndon, VA 20170
Phone: PI: Topic#:	(703) 471-9310 Mr. Richard E. Engdahl AF 01-126 Awarded: 04APR01
Title:	Improved Interface Coating Facility for Ceramic Composites
Abstract:	Synterials has in place a facility that will coat long lengths of ceramic cloth such as CG Nicalon with multilayer coatings based on the BN system. This coating capability is the first step in affordability. The next issue that needs to be addressed is reproducibility. This proposal directs effort at qualifying a sensor system that will determine the composition and the deposition rate of the coating process on-line. One candidate sensor has been evaluated in a preliminary manner and two others are to be included in the study. To qualify the sensor system, it is proposed to capture, on-line, deposits that can be measured in about a minute without interrupting the coating of the cloth. This measurement will be made multiple times during the coating of long lengths of cloth. The precision of the sensor will be evaluated by comparing the results of the sensor values with that measured by Auger and SEM on the same coating samples. Phase 2 will start once the precision of the sensor system has been established. In Phase 2 multiple meter lengths of cloth will be processed with specified on and off design conditions and the cloth used to produce composite evaluation panels. These panels will be tested under various loading and environmental conditions. In parallel with the sensor work will be work to fully automate the existing manual control system. This computer controlled system will include special warning and alarm features designed to assure the coating quality.Reproducible, low cost interface coatings are required to assure that the predicted properties of a given composite will be achieved in every similarly produced composite. This assurance that the properties used in a design will be faithfully produced in production composites is essential for both military and commercial applications. This program represents an important step in moving a composite system from research to production.

KNOWLEDGE BASED SYSTEMS, INC. 1408 University Drive East College Station, TX 77840
Phone: PI: Topic#:	(979) 260-5274 Dr. Jayakumar Muthusami AF 01-127 Awarded: 02MAY01
Title:	Advanced NDI Techniques using Data Fusion
Abstract:	The ultimate goal of this effort is to develop state-of-the-art software that performs Data Fusion on NDT techniques such as eddy current, ultrasonic, edge of light detection, Superconducting Quantum Interface Device (SQUID), X-ray and other leading NDT techniques that is of value to the Airforce corrosion detection program. The Phase I and Phase II research proposed would ultimately lead to usage of NDT data, environmental severity index, age, and corrosion growth rate information to predict structural state at a specific time, pit depth, area out, morphology, hidden corrosion, etc. This research would result in reliably estimate of the remaining life cycle to plan condition based maintenance (CBM) of the aircraft. The proposed research would result in significant manpower and machine time savings. Reliable prediction of corrosion is one of the single most important aspects for the condition-based maintenance (CBM) of the aircraft system.Direct cost of corrosion maintenance for the year 1997 is $800 Million and 50% of this cost is due to aging aircraft's KC-135, C-141, and C-5. The technology developed in this research would reduce the life cycle cost and increase the availability of aircraft's resulting in substantial savings.

PHYSICAL OPTICS CORP. 20600 Gramercy Place, Bldg. 100 Torrance, CA 90501
Phone: PI: Topic#:	(310) 530-7892 Dr. Norbert Fruehauf AF 01-128 Awarded: 11MAY01
Title:	Two-Photon Photocuring for Non-Autoclave Fabrication
Abstract:	The U.S. Air Force is seeking an innovative flight line repair technology for non-autoclave fabrication of polymers that can be used to repair cracks in Radar absorbing materials, Radar absorbing structures, and gap treatment composite materials. To address this need, Physical Optics Corporation (POC) proposes to develop a new two-photon based photopolymerization process and demonstrate the viability of a unique handheld photocuring device based on that process. The device will be based on leading edge two-photon chromophore materials. In Phase I, POC will demonstrate the feasibility of the deep-penetration, two-photon photocuring process by screening available high performance chromophores, selecting appropriate resins, and experimentally establishing optimum process parameters for successful deep penetration. The Phase I effort will also include preliminary investigation of a user-friendly, hand-held photocuring device. In Phase II, POC will optimize its new two-photon curing technology and develop a unique photocuring device based on this technology. In Phase I, POC will also initiate activities, such as identification of source of other financial support that will ensure successful commercialization of the developed technology in Phase III.The new two-photon photocuring technology offers unique deep penetration depth photocuring, ease of use in a highly portable system, precise control of curing process parameters, resulting in high reproducibility and yield, and reduced maintenance Man Hours per Flight Hour. It has good potential for fast prototyping and fabrication of micro-optical structures and componets such as waveguides, micro-gratings, or new applications for POC's proprietary light shaping diffusers.

TRITON SYSTEMS, INC. 200 TURNPIKE ROAD Chelmsford, MA 01824
Phone: PI: Topic#:	(978) 250-4200 Dr. Huaibing Liu AF 01-128 Awarded: 13APR01
Title:	Two-photon Induced Photopolymerization and Photocuring with Improved Efficiency
Abstract:	Triton Systems responds to the Air Force need to determine the feasibility of developing a unique 2-photon laser-induced process for the effective non-autoclave on-aircraft repair of RAM, RAS, and gap treatment resins and elastomers. We propose to demonstrate a uniquely effective 2-photon polymerization and curing process for urethane-acrylic and epoxy-silicone gap treatment elastomers. Our key innovation is the use of specific photo-initiators and co-initiators that will improve the primary system efficiency, the extent of resin curing at modest fluences, and the depth of curing (beyond the depth obtained using conventional uv-curing processes). The improved 2-photon processing will be performed under Ti:sapphire laser illumination, at field-operable powers, and below the threshold of laser damage gap treatment elastomers. In Phase I we will screen unique Triton initiator systems using Air Force 2-photon chromophores, and will demonstrate at least one elastomer- 2-photon cured system at reasonable depth. In Phase II we will optimize one or more best systems to achieve a repair process to a 1" depth with field portable equipment. Phase III will produce resin systems and will develop dual use applications in industry.Two-photon induced polymer processing and fabrication technique has the advantages of potential portability, spatial control, and short cure times as well as enhanced depth of cure. It will be utilized for flight-line repairs of aircraft structures such as Radar Absorbing Material, Radar Absorbing Structure and gap sealants, significantly reducing Maintenance Man Hours per Flying Hour

ASSEMBLY GUIDANCE 315 Littleton Rd. Chelmsford, MA 01824
Phone: PI: Topic#:	(978) 244-1166 Mr. Scott Blake AF 01-129 Selected for Award
Title:	Application Techniques of Appliques for Aircraft Topcoats
Abstract:	Using appliqu�s to replace paint requires a "total appliqu� process solution" in the form of an "Applique Process Cell": an integrated set of technologies and methods which address ALL of the process requirements so as to utilize appliqu�s efficiently, especially reducing trimming requirements when covering complex curved surfaces. The required enabling technologies for an Appliqu� Process Cell currently exist in mature forms in disparate applications and locations. Assembly Guidance.has developed several of these enabling technologies and has established relationships with companies which can provide all of the other hardware and software components. The proposed team includes Lockheed Martin, 3M, a US Air mechanic familiar with appliqu�s, a metrologist experienced in capturing aircraft surfaces, a CAD engineer specializing in cutting and applying material to aircraft surfaces, a high accuracy material cutting specialist, and a Principal Investigator experienced in quality process development in manual placement of sticky material on complex surfaces, kitting and process-guiding displays (a Tibbetts Award Winner). This team will test, document, and refine the "total applique process" in the area of repeatable application on complex curves with reduced trimming. The result will be descriptions of the methods, technologies, costs and benefits for addressing complex surfaces with Applique Process Cells. Benefits: lower costs in installing appliqu�s, lower costs/improved performance in aircraft finishing, significant reduction in environmental impact in aircraft finishing stripping. Applications: All Military and Civilian Aircraft, Maritime

KAZAK COMPOSITES, INC. 32 Cummings Park Woburn, MA 01801
Phone: PI: Topic#:	(781) 932-5668 Mr. James Gorman AF 01-129 Awarded: 25APR01
Title:	Novel and Automated Installation Methods for Aircraft Appliqu�
Abstract:	Appliqu� has demonstrated the potential to save literally billions of dollars in life cycle cost for DOD aircraft as paint replacement, yet very little work has been done to overcome the largest impediment to its adoption; that is, high installed cost. The majority of this cost arises from installation labor, yet appliqu� installation to date has remained almost exclusively a skilled manual operation. Under this program, KaZaK shall develop innovative automated equipment and procedures to address the major installation cost drivers - compound curvature, edge sealing, large area application and protruding head fasteners. Specific concepts to address each of these problems are discussed herein. Furthermore, KaZaK has formed a world-class team to address this challenge comprised of the appliqu� producer, two airframe prime users and an experienced appliqu� installation firm in the bus market to consult on best commercial practices.We anticipate that at the conclusion Phase I, the technology developed will make substantial progress toward increasing appliqu� installation rates from roughly 5 square feet per labor-hour achieved on current aircraft programs to rates of 75 square feet per labor-hour routinely achieved in the commercial "bus wrap" market. Two specific equipment and installation processes will be developed to promote these goals. These will be demonstrated on real airframe sections provided by our partners on this program.

FRACTAL SYSTEMS, INC. 14200 Carlson Circle Tampa, FL 33626
Phone: PI: Topic#:	(813) 854-4332 Dr. Matt Aldissi AF 01-130 Awarded: 02MAY01
Title:	Lightweight Radar Absorbing Materials using Functionalized Binders in Aqueous Media
Abstract:	Current radar absorbing materials (RAMs) are heavy and require hazardous materials for processing. Having a lighter weight binder with a suitable morphology, combined with environmentally friendly solvents to produce RAMs would offer significant advantages in manufacturing and in the field. Fractal Systems, Inc., in collaboration with our aerospace partners, proposes to develop RAMs through manipulation of the polymeric binder and the proper choice of the solvent using existing fillers such as ferrites. In Phase I, we will develop several dispersion formulations for fabrication of coatings and sheets whose absorption characteristics will be determined by our partners. Other characterization techniques will be used to ensure that the overall material quality is likely to meet the Air Force and end users' requirements. In Phase II of this program, we will optimize the different characteristics of the material for producing practical formulations geared towards making lighter non-hazardous RAMs that will qualify for specific applications (one is air-born and another is naval-based). With direct input form and active participation by our aerospace partners, this effort is likely to result in commercially viable products.In addition to stealth aircraft, air-born targets and naval-based systems, ground-based electronic equipment in the battlefield, low-cost, efficient and lightweight radar absorbing materials can find use for commercial avionics and filtering applications in electronics susceptible to radar/ microwave frequencies.

TRITON SYSTEMS, INC. 200 TURNPIKE ROAD Chelmsford, MA 01824
Phone: PI: Topic#:	(978) 250-4200 Mr. Guy Rossi AF 01-130 Awarded: 09MAY01
Title:	Low Weight, Durable, Radar Absorbing Paints for Aircraft Structures
Abstract:	Triton Systems proposes to develop novel, durable, low weight radar absorbing paints that will reduce the Radar signature of aircraft. Our approach will significantly reduce the weight of ferromagnetic particle/pigment-based paints via novel binder additives to create up to 50% fraction porosity within the binder. The net result will be a significant reduction in total weight of the coating. In addition, we will significantly reduce volatile organic compounds (VOC) and Hazardous Air Pollutants (HAP) due to the reduced solvent levels necessary with the reduced levels of binder material. We will carefully optimize the polymer resin chemistry and use unique clay nano-fillers to improve the mechanical and barrier properties of the polyurethane matrix. This will allow us to maintain adequate abrasion resistance, flexibility, chemical resistance and moisture barrier to protect the underlying aircraft, despite the addition of a significant porosity to the coating. The net result will be a uniform coating, applied with simple low cost methods such as spray coating at reduced VOC levels. These coatings will reduce the weight, cost, and environmental impact associated with RCS reduction.Durable, abrasion- and Chemically resistant RAM coatings will find application on a variety of Military aircraft. It will find application on ship structures and other military vehicles. In addition it will find application for screening and shielding for TV and cellular communications in civilian markets.

TEXAS RESEARCH INSTITUTE AUSTIN, INC. 9063 Bee Caves Road Austin, TX 78733
Phone: PI: Topic#:	(512) 263-2101 Dr. Michael L. Dingus AF 01-131 Awarded: 11MAY01
Title:	Ultraviolet Light Curing Materials for Field Level Composite Repair
Abstract:	Rapid, high quality, on-aircraft repair techniques for fiberglass composite components are required to support the Air Expeditionary Force concept. Current field level repair methods use thermally accelerated adhesive bonding to restore the original design strength of the composite laminate. Several problems exist with on-aircraft thermally cured repair methods. Airframe structural members act as heat sinks, increasing power demands and making it difficult to obtain a uniform cure temperature profile. Current resin systems require low temperature storage to avoid premature degradation, increasing storage cost and support complexity. UV cure resins avoid these problems, but it is difficult to develop a UV cure resin system that meets military aircraft service temperature requirements. Texas Research Institute Austin, Inc. (TRI/Austin) proposes the development of new high temperature UV cure resins for composite aircraft repair. To integrate the new resins into the required "turnkey" aircraft repair solution, TRI/Austin will team with Abaris Training Resources, Inc. Abaris's extensive aircraft repair qualifications will be coupled with TRI/Austin's 25 years of experience in developing and testing high performance resins and composites for the DoD. Repairs will be performed on test coupons and actual aircraft components. Their physical performance will be compared with similar standard thermal repairs. Candidate application airframes include the F-22 and the JSF. In addition, fiberglass components are part of virtually every modern military and civilian aircraft platform - including fiberglass radomes, which are commonly damaged during service. Common fiberglass aircraft components include wing and tail surface leading edges, control surface skins, and fairings (including large compound-curved wing-to-fuselage fairings on everything from light aircraft up to 747's). Composite interior panels are used in sidewalls, floorboards, overhead baggage bins on airliners, and cargo compartment liners. The vast majority of structural components that must be electromagnetically transparent contain fiberglass or quartz fiber reinforcement.

COI CERAMICS, INC. (formerly Engineered Ceramics), 9617 Distribution San Diego, CA 92121
Phone: PI: Topic#:	(858) 621-7454 Mr. Steven C. Butner AF 01-132 Awarded: 10APR01
Title:	Development of Improved Aircraft Thermal Protection Materials
Abstract:	Systems that have used tile insulations, such as NASA's Alumina Enhanced Thermal Barrier (AETB) and Fibrous Refractory Composite Insulation (FRCI), have long fought against the high cost, limited damage tolerance, and complicated attachment schemes of these materials. Efforts to improve the tiles with hardness coatings have not provided an adequate solution to the problem. The limitation has been the limited strength and damage tolerance of the tiles themselves. Until a viable solution to this problem can be found, vehicles will continue to bare the extremely high cost of maintenance, repair and replacement of tiles. In this Phase I proposal, COIC proposes to develop a new version of AETB with 2 - 5 times the strength and impact tolerance of current versions of the material at a reduced cost. This objective will be achieved through the development of a new composition and manufacturing process for the material.Benefits of this insulation system over existing insulations will be vastly reduced repair and maintenance costs, and lower material costs. Other potential applications for a strengthened tile would be used as a structural core material. The advantage of composite sandwich panel design is well known in the organic composites industry.

ANVIK CORP. 6 Skyline Drive Hawthorne, NY 10532
Phone: PI: Topic#:	(914) 345-2442 Dr. Robert Sposili AF 01-133 Awarded: 22MAR01
Title:	Sequential Lateral Solidification of Ultra-Thin Silicon Films for SOI Applications
Abstract:	Compound semiconductors enable numerous important electronics and optoelectronics applications. They are commonly produced via epitaxial deposition methods, but the existing compound semiconductor substrate materials are expensive, highly defective, and not available in large sizes. The use of silicon substrates is attractive because of their low cost, low defect density, and large sizes. However, lattice mismatch poses a serious problem because it leads to defect generation in the epitaxially grown films. So-called compliant substrates, in which the surface atoms can rearrange to accommodate the mismatch, offer a solution; ultra-thin (5 nm) silicon-on-insulator (SOI) films have been identified as an attractive candidate compliant substrate material. Unfortunately, commercially available SOI materials are not sufficiently thin, and cannot be reduced to the desired thickness. Herein we propose to utilize the sequential lateral solidification (SLS) process - an excimer laser crystallization process that can convert as-deposited amorphous or polycrystalline silicon films into large single-crystal regions - to create ultra-thin SOI-quality silicon films on oxidized silicon wafers. SLS was developed to enable the fabrication of high-performance thin-film transistors (TFTs) on low-temperature substrates, but given the high quality of the crystalline silicon films that it can produce, it has been identified as a potential competitor to traditional SOI methods.The anticipated benefit of the work is the creation of a method and equipment for producing ultra-thin SOI-quality silicon films on insulators, such as SiO2, with the intended purpose of using them as compliant substrates for compound semiconductor heteroepitaxial deposition. Currently, there are no methods capable of providing this material. The commercial benefits encompass all of the electronics and optoelectronics applications for which compound semiconductors are used. Furthermore, the technology is relevant to other applications, such as TFTs, that are based on SOI materials.

GRATINGS, INC. 2655-A, Pan American Freeway Albuquerque, NM 87107
Phone: PI: Topic#:	(505) 345-9564 Dr. Saleem H. Zaidi AF 01-133 Awarded: 12APR01
Title:	Heteroepitaxial growth on nanostructured silicon Surfaces
Abstract:	This phase I SBIR research effort addresses low-cost, large area development of a universal, compliant silicon substrate technology for heteroepitaxial growth of compound semiconductor thin films. Due to lattice and thermal expansion coefficient mismatches, pseudomorphic growth beyond critical thickness is not possible. Several models predict significant relaxation of these constraints due to various stress relief mechanisms available in thin film and 3D nanoscale features. We propose application of 10-50-nm linewidth 3D Si structures for heteroepitaxial growth applications. By suitable choice of processing parameters, these structures are isolated from the thick substrate to act as highly compliant patterned thin films. The stress relief provided by these nanoscale structures in SOI configuration has helped improve quality of GaN films. We propose application of these techniques for Ge and GaAs growth in collaboration with Emcore to improve space solar cells. By replacing Ge substrates with Si, substantial cost and weight reductions can be achieved. Finally, these structures are also expected to find applications in several related material systems.Space Solar Cells Lasers Light emitting diodes Si-on-insulator

THIRD WAVE SYSTEMS, INC. 7301 Ohms Lane, Suite 580 Minneapolis, MN 55439
Phone: PI: Topic#:	(952) 832-5515 Dr. Troy Marusich AF 01-134 Awarded: 11APR01
Title:	Improved Titanium Machining Process
Abstract:	While recent advances in high speed machining (HSM) of aluminum materials have successfully achieved significant reductions in cost of aerospace structures, these advances have not been successfully applied to titanium material components. Machining costs are a major cost driver in these components, so a meaningful increase in metal removal rate capability will have a significant economic benefit. Primary barriers to achieve high metal removal rates of titanium include: 1) the lack of validated analytical development tools to reduce the dependency on testing trial and error methods, 2) the high cost and inefficient methods for testing new machining concepts, 3) the inherently different machining characteristics (i.e. material characteristics and behavior during machining) of titanium, 4) the high cost of titanium material itself. The focus of this project will be to develop and demonstrate the application of new and existing modeling technology to cost efficiently reduce the first 3 of 4 barriers identified above. This will be accomplished by: 1) the use of validated software modeling technology specifically developed for modeling metal cutting, (the same baseline technology which was instrumental in HSM of Al), 2) the use of modeling techniques to significantly reduce the need (and cost) for testing while increasing the efficiency and successful implementation of new concepts, 3) the use of validated titanium material modeling technology already developed specifically for machining applications. The benefits to be received are: 1. The immediate commercial availability of a validated software modeling platform for the analysis and development of titanium cutting processes. 2. An easy-to-use modeling environment that can be used for both process modeling and cutting tool development. 3. The development of a new validated analytical tool that will significantly reduce the amount of testing trials (and hence, schedule and cost) for developing new cutting methodologies. 4. A more fundamental scientific understanding of the titanium cutting process. 5. A tool that will provide an affordable research method for analyzing, developing, and evaluating HSM techniques specifically for titanium materials. 6. Reduced risk and higher success rates for actual cutting tests that are conducted. Commercial applications include in the broadest sense all machining of titanium components and could very easily be extended into nickel-alloy materials as well. Specifically for the scope of this project, Ti-6Al-4V will be the material of choice. The primary application is its' use in aerospace structural and engine components, both commercial and military. Specific applications will include: 1. Turning machining processes, including boring, reaming, inside diameter and outside. 2. Milling machining processes, including end milling, pocket milling, etc. 3. Cutting tool development; geometries, substrates, use of coatings, development of operating specifications, etc. As example, a typical aerospace engine component may cost $150,000 - $250,000 by the time all the machining is performed. Relatively small productivity increases of 10% - 20% in parts of this high cost return large economic benefits. Multiplied by several hundred units per year, this easily begins to return millions of dollars in savings for just one component. Likewise the successful application of HSM techniques in titanium may allow HSM to economically replace other less desirable methods such as chemical etching. This could potentially reduce process costs on these same type of components by 50% or more, while also eliminating a hazardous, non-desirable type of process. We believe the applications and potential for economic return is well known by the industry. However, industry lacks the appropriate tools, capability, and fundamental scientific understanding to be able to economically develop and implement the next higher order level of capability. Instead choosing to rely on present techniques that mainly are past experience and trial and error testing methods.

UES, INC. 4401 Dayton-Xenia Road Dayton, OH 45432
Phone: PI: Topic#:	(937) 426-6900 Dr. Amarendra K. Rai AF 01-134 Awarded: 11APR01
Title:	Development of Ceramic Tool Material and Advanced Multifunctional Coatings for Improved Titanium Machining Process
Abstract:	This proposal seeks to develop improved titanium machining process. Titanium alloys widely used in aerospace industry, are one of the most difficult workpieces to machine, which has become a major limitation in manufacturing. Unlike steel and aluminum based alloys, titanium cannot take advantage of the high cutting speeds afforded by the use of current state-of-the-art ceramic cutting tools due to its high reactivity with available ceramic tools at the high temperature generated during machining. Moreover conventional coatings which are successful for high speed machining of steel and aluminum do not provide any improvement in titanium machining. For improved titanium machining we propose to develop a new class of ceramic composite cutting tools based on yttrium aluminum garnet (YAG) and advanced multifunctional coatings utilizing state-of-the-art large area filtered arc (LAFAD) technology. Attention will be focussed to make the proposed composite and coatings highly chemically compatible with titanium. Also during processing of composite and coatings, efforts will be directed to lower the temperature rise during titanium machining. Such YAG based cutting tools and advanced coatings could provide increased machining rates of titanium and increased tool life.Successful completion of the program will provide demonstrated knowledge about the YAG based ceramic cutting tools and advanced coatings for the improved titanium machining process. The acquired knowledge would have broad commercial applicability due to the large number of commercial airframes and engines that are fabricated from titanium.

OPTICS 1, INC. 3050 E Hillcrest Drive, Suite 100 Westlake Village, CA 91362
Phone: PI: Topic#:	(603) 432-2148 Mr. Michael E. Couture AF 01-135 Awarded: 11APR01
Title:	Design of New Night Vision Goggle (NVG) Optics
Abstract:	New helmet mounted device concepts have demonstrated the need for fast and more photon efficient optical systems operating in the visible from 400 nm to 700 nm. Current NVGs have been designed for the near IR, from 600 nm to 900 nm. This shift in waveband requires a change in the glass selection due to the different dispersion characteristics of most glasses at the shorter wavelengths. Because of the greater dispersion in the visible, specifically in towards the blue spectrum, chromatic aberration becomes more difficult to control. In addition, packaging to meet a specific helmet layout configuration also becomes a challenge. Packaging can be very simple with no folds, but this configuration results in a large shift in the helmet center of gravity away from the user causing significant fatigue for the user. Configurations with multiple folds allow the CG closer to be closer to the user at the cost of added complexity.Development of NVG and NVG style enhanced vision systems in the visible waveband has the benefit of substantially reduced cost from classical NVG systems principally due to the low cost detectors available. The low cost will enable these systems to be widely distributed among military field troops and allow normal operations to continue well into twilight hours. Additionally, the potential low cost may allow introduction of such products into the commercial arena for applications such as hiking and hunting.

METRATEK, INC. 9858 Main Street Fairfax, VA 22031
Phone: PI: Topic#:	(703) 293-9040 Mr. Raymond L. Harris AF 01-136 Awarded: 18APR01
Title:	Broadband LO NDE Sensor Technology (BLONDE)
Abstract:	The proposed R&D will develop a hand-held tool for real-time broadband nondestructive evaluation of low observable materials and structures on the flight-line. The unique principle of operation has already been demonstrated in our IR&D program and is well-suited for this type of measurement. The system is easy to operate. It detects and locates damage, and quantifies electromagnetic materials properties over the 2 - 18 GHz frequency range. A bench-top prototype tool will be developed and demonstrated In Phase I . In Phase II, we will field a system that can be evaluated for its fidelity in measurements, repeatability, and accuracy on real LO aircraft. The proposed approach has high probability of success because of METRATEK's strong history of successful innovation in RCS measurement technology and because we have already laid the groundwork for success by verifying the unique principle of operation of this device.The proposed system fills a major USAF need for a hand-held tool to provide rapid assessment of the stealth qualities of on-aircraft materials. The tool that we will develop provides a major increase in stealth aircraft availability by avoiding unnecessary repairs, and increases survivability by assessing potential detectability problems before mission assignment and/or take-off. The concept associated with this tool can be exploited for commercial applications such as vehicular radar sensors, intrusion alarms, assembly line parts inspection systems, and fuel tank and pipeline internal inspection systems.

OPTOMETRIX, INC. 4134 Lind Avenue SW Renton, WA 98055
Phone: PI: Topic#:	(425) 251-6363 Dr. R. Aaron Falk AF 01-136 Awarded: 20APR01
Title:	Broadband LO NDE Sensor Technology (BLONDE)
Abstract:	The purpose of this project is to combine two developing technologies, near field microwave sensors and short pulse microwave generation/detection, into a compact, real-time tool for test and evaluation of low observable materials and structures. This tool is critical to field maintenance of stealth vehicles, potentially affecting the health and safety of both the vehicle and its occupants. For the last three years, OptoMetrix has been working with the Boeing Company to develop a free-space broadband microwave spectrometer for use on stealth vehicles. The core technology of this instrument is the generation and detection of short (10's of picosecond) microwave pulses, which provides a wide bandwidth in a simple, compact package. At the same time, the Boeing Company was developing near field microwave probes for narrow band interrogation of material properties. The combination of these two technologies for producing a broadband, near field tool promises to meet or exceed the demands of field maintainability and thereby minimize the risks to personnel and equipment.Tool for real-time evaluation of low observable material and structures. Tool for real-time evaluation of metal corrosion under paint or other layered materials. Tool for real-time evaluation of voids and defects in composite materials.

ADTECH SYSTEMS RESEARCH, INC. 1342 N. Fairfield Road Beavercreek, OH 45432
Phone: PI: Topic#:	(937) 426-3329 Dr. Som R. Soni AF 01-137 Awarded: 11APR01
Title:	Strain Rate Effects in Ballistic Analyses of Bonded & Co-Cured Composite Structures
Abstract:	A program is proposed that will extend (and build upon) the work already started by the Survivability Group of the Composites Affordability Initiative, Pervasive Team in developing methods for analyzing the effects of ballistic and hydrodynamic ram (HRAM) loading and damage in bonded/co-cured composite structures. Specifically, the objective will be to remedy a major shortcoming of current HRAM finite element codes, which are unable to accurately model the details that differentiate one joint design from another. The incorporation of stitching, z-pinning, co-curing, and bonding of the joints leads to different failure modes and paths. This is the area in which most work will be performed - in the proper selection of failure criteria within the joints as well as the entire model. Presently, the state-of-the-art is to use an elastic-plastic smeared properties technique in modeling the structure and "fuze elements" to model the joints. This program will greatly improve upon the current practices by developing cohesive elements, whose material properties can be determined by testing and incorporated into the HRAM finite element models. Commercialization of the herein proposed research and development activity is in an area where AdTech has demonstrated successes in the past; however, the technology area is broader in scope. Thus we envision commercialization of a software module that can be added to existing, general purpose, fluid structure codes. These would include such codes as: (1) LS Dyna by LSTC, Inc., (2) MSC Dytran, (3) ALE 3-D, (4) CALE, (5) the Sandia CTH code couled to the old Dyna 3-D code for buildings, and (6) the Allegra Code. Further, the Cohesive Element 2-D code is being developed into a 3-D code, and our module would be adaptable to that code as well. Some of the key people associated with several of these codes have already been contacted and have expressed interest. User companies of these established codes are already comfortable with them, have historical data based upon them, can make comparative assessments, and thus are oftentimes reluctant to change --- even though there may be a known better software product available to them. At the same time, they may be quite receptive to adding an enhancement module to an existing code in order to expand its usefulness.

MATERIALS SCIENCES CORP. 500 Office Center Drive, Suite 250 Fort Washington, PA 19034
Phone: PI: Topic#:	(215) 542-8400 Dr. Chian-Fong Yen AF 01-137 Awarded: 04APR01
Title:	Strain Rate Effects in Ballistic Analyses of Bonded & Co-Cured Composite Structures (MSC P1G26-106)
Abstract:	The objective of the Phase I study is to develop a fully integrated design tool for performance evaluation of bonded/co-cured composite structures subject to ballistic and hydrodynamic loading. This tool will have the applicability in the development of emerging military air vehicles with enhanced hydrodynamic ram/ballistic survivability. Previous research work performed at Materials Sciences Corporation (MSC) has successfully demonstrated the integration of advanced composite progressive failure models into LS-DYNA for accurate prediction of deformation and failure of various composite structures subjected to ballistic and blast impacts. The Phase I program will extend the current MSC failure models to include strain-rate dependent progressive failure for bonded and co-cured composite materials with z-reinforcements. The developed material models will be critically evaluated and calibrated by correlating with existing rate-dependent data of stress-strain response as well as bonded composite joint failure behavior. Lockheed Martin Aeronautics Company will provide existing test data and engineering consultation in this Phase I program as a subcontractor to MSC.This program will provide a design tool with enhanced analytical capability for modeling of a composite bonded structure on future air vehicles. This technology has excellent potential in survivability design of various composite structures. Application will include both military and civil markets such as aircraft, armored vehicles, surface marine craft and submarines, helmets, and blast resistance structures.

EIKOS, INC. 2 Master Drive Franklin, MA 02038
Phone: PI: Topic#:	(508) 528-0300 Mr. Paul Glatkowski AF 01-138 Awarded: 11APR01
Title:	Next Generation Polymeric Optical Host Materials
Abstract:	Eikos, Inc. will develop thermoplastic optical host materials that have high laser damage threshold (LDT) for next generation optical components. The world class team of researchers brought together at Eikos and Virginia Polytech will develop these materials with high single and multiple pulse laser damage thresholds, and investigate the underlying material structure-property relationships to understand the mechanisms that give rise to increased laser damage thresholds. These polymers offer substantial advantages over current PMMA-based materials including thermoplastic processing, very high refractive indices, higher thermal stability, excellent blending characteristic with both organic and inorganic dyes, and additional benefits including ionization and atomic oxygen resistance. These new polymers are the state-of-the-art in transparent thermoplastic materials and are being developed for several commercial applications including next generation canopies and optical lenses. The mechanical properties and optical quality of these materials are perfectly suited for their development in a variety of applications including optical limiting, optical signal processing, and replacement of current PMMA or polycarbonate products. The range of properties exhibited by these polymers will allow us to develop a detailed structure-proerty relationship for high laser damage threshold. Eikos has already started commercialization of these materials with a major consumer products company.In addition to these laser specific applications, perhaps the most robust markets for these materials lie in the general realm of transparent plastics. The transparent plastic market is a multibillion dollar market, and include industries like packaging, building products, medical products, and electronics. Where these particular materials will have advantages is in the high temperature applications where conventional PET, PMMA, or polycarbonate materials fail to perform. These materials also offer some unique properties such as high dielectric constant and refractive index, which has potential uses in linear optics and electronic devices. Finally, these materials are inherently atomic oxygen resistant, which will make them particularly suitable for transparent polymer applications in space.

PHYSICAL SCIENCES, INC. 20 New England Business Center Andover, MA 01810
Phone: PI: Topic#:	(978) 689-0003 Dr. Dennis P. Pacheco AF 01-138 Awarded: 11APR01
Title:	Development of Optical Host Materials with High Laser Damage Thresholds
Abstract:	Physical Sciences Inc. (PSI) proposes to develop a high-damage-threshold host material for high-power or high-fluence optical applications. The goal is to produce a material which has a damage threshold at least an order of magnitude higher than that for polymethyl methacrylate (PMMA), and which will permit incorporation of a wide variety of organic dyes up to at least the millimolar concentration level. This effort will be a collaboration between PSI and the world-renowned Polymer Synthesis Laboratories at UMass Amherst, who will be a subcontractor for this work. In Phase I, we will synthesize a number of acrylic-based materials covering a range of chemical structures and material properties. These candidates will be subjected to optical damage testing in order to demonstrate laser-hardened formulations, and to understand the relationship between polymer structure and laser damage threshold. The Phase II work will utilize the candidates identified in Phase I to produce a host material which is optimized for both damage resistance and dye compatibility. Detailed structure-property relationships will be established. Successful progress of the program will be validated in each phase through the testing of selected samples at AFRL/MLPJ using their in-house capabilities.An optical host material with both high damage resistance and excellent dye compatibility will represent a major breakthrough for advanced sensor protection and solid-state dye lasers. In the area of sensor protection, for example, safety eyewear can be developed which is compact, robust, and effective against agile laser sources. In the area of solid-state dye lasers, compact, wavelength-agile devices can be produced for a variety of military and medical applications.

EIC LABORATORIES, INC. 111 Downey Street Norwood, MA 02062
Phone: PI: Topic#:	(781) 769-9450 Dr. Krishna C. Mandal AF 01-139 Selected for Award
Title:	Flexible, Light-Weight, and Solid-State Nanocrystalline TiO2-Polymer Solar Cells on Plastics
Abstract:	This SBIR Phase I project proposes to develop flexible, lightweight, highly efficient, and low-cost dye sensitized nanocrystalline TiO2 solar cells. The proposed all-polymer and flexible versions of Gr�tzel cells made by continuous coating and lamination process will be very attractive for deployable shelters at a projected cost of ~$ 0.40/Wp. Although dye-sensitized solar cells (DSSC) show promise as low-cost photovoltaic alternatives, considerable problems remain with regard to their use of liquid redox electrolytes that are to difficult to seal and maintain for the lifetime required for large-scale economic power production. EIC Laboratories proposes to investigate and develop both ionically and electrically conducting polymers as potential replacements for liquid electrolytes in the DSSCs. Furthermore, the laminated polymer composite counter electrode and low temperature processing of screen-printed TiO2 layers on flexible plastic substrates proposed here will make DSSCs suitable for direct attachment to tentage and other textiles. The goal of the Phase I research is the first demonstration of a fully flexible, all-polymer dye sensitized solar cell with a conversion efficiency of >5% and its lamination to a tent textile substrate.With growing concerns over the dwindling nature of fossil fuel supplies, global warming and climate change, photovoltaic technology is becoming increasingly viable as an alternative energy source. The proposed all-polymer and flexible version of dye-sensitized integrated solar cells will be very attractive for terrestrial and space power generation applications including Air Force deployable structures, where high specific power and mechanical flexibility are needed at a a very low production cost. Other low power applications include consumer electronics, smart cards, sensors, electrochromic widows, mirrors and eye ware.

NANOSONIC, INC. P.O. Box 618 Christiansburg, VA 24068
Phone: PI: Topic#:	(540) 953-1785 Dr. Kristie Cooper AF 01-139 Selected for Award
Title:	Ink Jet Print Self-Assembly of Mechanically Flexible Thin Film Photovoltaic Fabrics
Abstract:	This Air Force Phase I SBIR program would demonstrate the feasibility of ink jet print electrostatic self-assembly (ESA) processes for the low-cost fabrication of flexible photovoltaic arrays directly on fabric material. ESA processing involves the coating of substrate materials by the alternate adsorption of anionic and cationic complexes of polymers, metallic nanoclusters and other molecules from water-based solutions at room temperature and pressure. By controlling the molecules deposited in each monolayer of the resulting multilayer thin film, optoelectronic devices with high efficiency may be formed. Specifically, photon-to-electron conversion with high quantum efficiency can be achieved in layer-by-layer polymer dye/nanocrystalline semiconductor films, due to the high effective inter-particle surface contact area at the molecular level, and by using metal nanocluster/poly-dye multilayers to enhance optical absorbance. NanoSonic's recent work in this area, in cooperation with a large U.S. aerospace contractor, has demonstrated such high quantum efficiencies in ESA-fabricated devices, and the ability to form such functional thin films as coatings on mechanically flexible substrates. During Phase I, NanoSonic would work with that company to demonstrate the ability to reproducibly form deployable fabric photovoltaic fabric, and investigate methods to improve quantum efficiency, fabricate electrode interconnections and implement effective device packaging.Photovoltaic arrays that may be integrated directly with fabric materials offer unique opportunities for electrical power generation for both military and commercial applications. Power-generating tentage, clothing, and easily-deployed fabric would reduce the need for batteries and for separate mechanically rigid solar cell arrays in portable and mobile platforms. Low-cost processing methods such as ink jet print self-assembly at room temperature would allow cost-effective power generation.

SRS TECHNOLOGIES 500 Discovery Drive Huntsville, AL 35806
Phone: PI: Topic#:	(256) 971-7027 Mr. James C. Pearson, Jr. AF 01-140 Awarded: 11APR01
Title:	Processing of Tough, Fracture and Puncture Resistant Thin Films for Space Deployable Reflectors
Abstract:	SRS has developed a thin film processing technique that will enable a host of polymer solutions to be fabricated into precision large-scale membranes for space applications. The innovation presented for demonstration in the proposal is a polymer casting and curing technique that is based upon a transient heat flow air knife resulting in the curing of films under uniform conditions without the use of large curing ovens and costly high temperature substrates. This process is amenable to thermoplastic and thermosetting thin films or a combination of the two resulting in a laminated film which demonstrates the characteristics of a high strength tear resistant film.SRS will use the casting and curing technology of the transient heat flow air knife developed under this SBIR to enable new SRS business lines in the area of very large aperture concentrators, as well as make existent product lines (i.e., polyimide flat panel solar troughs) more efficient and cost effective. The technology demonstrated here will enable the production of larger size (>10m) without regard to mandrel, oven, and substrate size. SRS is currently involved (via the Dual Use Science and Technology (DUS&T) Electromagnetic Radiation Control Experiment (EMRCE)) with Boeing, Thiokol, the Air Force Research Lab, and NASA in developing a prototype 10m inflatable thin film concentrator with accuracy enough to meet RF and solar power generation requirements. Another promising market for large solar concentrators would be to power Satellite Transfer Vehicles used to rescue satellites boosted into wrong orbits or to collect space debris.

BLUE ROAD RESEARCH 2555 NE 205th Avenue Fairview, OR 97024
Phone: PI: Topic#:	(503) 667-7772 Mr. Eric Udd AF 01-141 Awarded: 04APR01
Title:	Life Cycle Performance Screening Using Fiber Optic Grating Sensor System for Composite Cryogenic Tankage
Abstract:	This Phase I SBIR will develop a methodology for monitoring the performance of composite cryogenic tanks through a system consisting of fiber grating strain sensors that will be integrated into the tank. The methodology will be developed through analysis, experimental testing of a demonstration article and subsequent evaluation of the results to check analysis. Blue Road Research will employ technology it has developed for both single and multiple axis fiber grating sensors allowing sensors to be mounted on the surface of the tank as well as at different depths in the demonstration article. The unique capabilities of the multi-axis fiber grating allow measurements of shear strain, transverse strain gradients and simultaneous strain and temperature that are beyond the capabilities of single axis fiber grating strain sensor technology.Developing technology and methodology that will support cradle to grave health monitoring of composite cryogenic tanks will be critical for both military and commercial reusable launch vehicles. Blue Road Research and Thiokol anticipate this technology will also be highly applicable to monitoring natural gas storage tanks.

MATERIALS & ELECTROCHEMICAL RESEARCH 7960 S. Kolb Rd. Tucson, AZ 85706
Phone: PI: Topic#:	(520) 574-1980 Dr. Stevan Dimitrijevic AF 01-142 Awarded: 13APR01
Title:	Fullerene-Dendrimer Optical Limiters
Abstract:	General objective of this program is to develop efficient optical limiters based on fullerene-dendrimer supramolecular structures. The scientific basis of the proposed program is nonlinear optical behavior of fullerenes and dependence of that behavior on interaction between fullerene molecules and matrix material. Reactions between fullerene and dendrimer molecules, studied at MER, resulting in formation of chemical bonds and yielding supramolecular structures that contain distinctive fullerene and dendrimer entities open the possibility of using dendrimers as convenient matrix for fullerene molecules. The controllability of the molecular sizes and shapes through precisely defined generations and controllability of molecular rigidity depending on size, shape and nature of dendrimers, make dendrimers a perfect matrix to investigate the validity of the concept that optical limiting properties of fullerenes could be tuned and optimized through interaction with matrix having variable rigidity. It is expected that the proposed concept can lead to the development of passive optical limiter with short reaction time, of the order of mili-second, and with sufficiently low saturation threshold in the interval between 0.6 J/cm2 and 1 J/cm2. The main goal of the Phase 1 is to synthesize fullerene-dendrimer supramolecules of different kinds, and to perform a thorough characterization of optical properties of obtained products in order to prove the defined concept. Optimization and definition of production procedure, and fabricating prototype coatings will be the main goal of the first part of the Phase 2, while the second part will encompass fabrication of prototypes, verification of quality of the products and preparations for commercial production. The main commercial potential of the anticipated fullerene-dendrimer molecular structure is in the market of optical protection at instrumentation/sensor level as well as in the domain of professional personal protection. Another potential field of commercialization may be the application as efficient self-lubricating materials and lubricant additives. Potential applications in electronic industry, electrochemistry and medical applications should not be excluded.

THOR TECHNOLOGIES, INC. 7600 Jefferson NE, Suite 9-115 Albuquerque, NM 87109
Phone: PI: Topic#:	(505) 296-3615 Dr. Stuart T. Schwab AF 01-142 Awarded: 13APR01
Title:	Novel Processing Methods for Space Optical Coatings
Abstract:	The mission of the U.S. Air Force has expanded to include responsibility for global intelligence and force projection-the ability to "reach out and touch someone" anywhere on Earth. To meet these mission requirements, the Air Force has greatly expanded its space technology development efforts. Space-deployable membranes have the potential to yield large gains in systems capabilities through the reduction of structural mass and launch volume. Because of the large distances involved, the shape of the membrane, particularly the reflective surface, must be closely controlled to achieve the desired resolution-even with the use of real-time holography correction methods. Materials and methods to control membrane shape or otherwise maintain optical performance are lacking. Thor Technologies, Inc. will team with Mound Laser & Photonics Center, Inc. (MLPC) and the University of Cincinnati (UC) to integrate three novel technologies into an innovative method of applying mesoscale patterns and devices onto polymer membranes and other substrates, and to characterize their electrical and optical performance. The Principal Investigator has considerable experience in application of synthetic chemistry to materials processing, MLPC has unique processing capabilities, and UC has unique characterization capabilities. The team is well qualified to prepare and characterize mesoscopic patterns and arrays. The proposed technology has the potential to impact a wide range of areas by enabling the facile preparation of microelectromechanical systems (MEMS) and other devices. It will enable the active membrane control required for space-based optical mirrors.

INFOSCRIBE TECHNOLOGIES, LTD. 1257B N. Fairfield Road Beavercreek, OH 45432
Phone: PI: Topic#:	(937) 431-8870 Dr. David A. Ress AF 01-143 Awarded: 12APR01
Title:	Engine Component Life Management Technology
Abstract:	This Phase I SBIR proposal plans to explore the concepts of data management for eddy current inspection of aircraft engine parts and the development of mining techniques utilizing intelligent agents. In addition, through the use of the internet, this proposal will explore the possibilities of sharing and analyzing data from remote locations. The data anayzed from this proposal will be used to assist in the determination of rotary engine parts for continued serviceThis developed technology will have a broad commercial and military appeal in understanding and extending the life of engine parts and thus reducing the cost of maintaining and servicing aircraft.

MATERIALS SCIENCES CORP. 500 Office Center Drive, Suite 250 Fort Washington, PA 19034
Phone: PI: Topic#:	(215) 542-8400 Dr. Anthony A. Caiazzo AF 01-145 Awarded: 03APR01
Title:	A Linked Engineering Knowledge Base Tool-Set for Textile Composite Material Forms (MSC P11G26-105)
Abstract:	It is expected that accelerated insertion of materials (AIM) will be facilitated through development of linked engineered material databases, that are capable of conducting quick virtual testing of new materials, that is supplemented by limited physical testing, rather than proceeding directly to complete experimental characterization. To address this need for reduced insertion time, Materials Sciences Corporation (MSC) proposes to develop and demonstrate computational simulation tools for quickly and reliably predicting the thermo-physical properties of textile fiber reinforced composite materials. The linked engineering knowledge base to be developed under this research program will be based on the Mathematicar style notebook interface, and constructed like the conventional experimental building-block approach. Individual modules that simulate microstructural behavior will provide input to structured material modules whose output are macro- or structural-level properties. Generation of limited data at any of the levels can then be expected to provide (limited) validation at other levels. In this fashion, the total amount of testing required to characterize a new textile fiber reinforced material can be reduced. Data interpretation tools, and a database function will be included. Development, validation and commercialization of this modular tool-set is the ultimate goal of this program.The leading applications for the AIM analysis tool-set to be developed and demonstrated by this research are AFRL, and U.S. Air Force advanced airframe, space systems, and engine component designers. In addition to these direct applications, MSC will pursue application of the products of this research to the commercial shipbuilding and aerospace sectors, the automotive industry and the oil exploration industry.

PHYSICAL OPTICS CORP. Electro-Optic & Holography Div, 20600 Gramercy Pla Torrance, CA 90501
Phone: PI: Topic#:	(310) 320-3088 Dr. Alexander Parfenov AF 01-146 Awarded: 13APR01
Title:	Ruggedized Durable Optical Fiber Connector
Abstract:	Physical Optics Corporation (POC) proposes the novel RUggedized Durable OpticaL Fiber Connector (RUDOLF) as a reliable fiber optic connector for use in harsh environments. POC's solution is based on extended beam principles tolerant of lateral misalignments, and leaves no voids in connector construction to be contaminated by fluids. POC' RUDOLF prevents alignment instability and potential failure of the optical connector as a result of contamination by coolant fluids. It is also tolerant to thermal expansion and minimizes optical losses. POC manufactured technology will make RUDOLF uniquely inexpensive, efficient, and durable. In Phase I POC will present a working demonstration of the RUDOLF connector, which in Phase II will be advanced to a preproduction prototype.RUDOLF connectors will be indispensable in harsh military environments and in commercial application requiring submersion in water, in the automotive industry, anywhere moisture, vibration, and thermal expansion make optical connections difficult. Cooling fluid cannot get into the connector and degrade optical performance. Connections by means of RUDOLF are repeatable, and optical losses are diminished.

ARETE ASSOC. P.O. Box 6024 Sherman Oaks, CA 91413
Phone: PI: Topic#:	(978) 475-4727 Mr. David M. Kane AF 01-152 Awarded: 06APR01
Title:	Streak Tube Imaging LIDAR Aimpoint Selection (STILAPS) Missile 3-D Targetting Sensor
Abstract:	The objective of this program is to create a sensor system design utilizing Micro Electro-Mechanical Machine Systems (MEMS) Beam Steering Mirror Arrays and leverage the Streak Tube Imaging LIDAR (STIL) demonstrated previously by Aret� . Addition of a MEMS beam steering array to the STIL technology will provide a low cost high accuracy 3d Imaging solution that meets the required to 2pi Steradian coverage at 1 kHz for a light-in-flight missile guidance system providing target detection and orientation determination specifically for aim point selection. Major Benefits of the STILAPS system as it applies to fuzing applications by providing exact orientation of the weapon relative to the surface of the target for terminal attitude sensing and aim point selection are as follows: � Dual Channel imaging for Detection and Characterization � Camouflage and Canopy Penetration capability � Haze and aerosol penetration capability � High resolution, 4m GSD over 2pi sr � 1m GSD over 0.62 sr within 2pi sr � Accurate range determination, 0.07m rms @ 4m GSD, 0.018m rms @ 1m GSD � Range Depth is adjustable in flight, with rDepth of 400m for the Detection Channel and 100m for the Characterization Channel � High Coverage Rates, 2p sr at 1kHz with laser PRF of 59 kHz The STIL is an integral part of Aret�'s current business base and implementation of this technology. Adding the ability to scan an area utilizing the MEMS mirror array beam steering approach will allow introduction of the STIL into a host of additional commercial and DoD markets. Aret� is actively investigating surface measurement and inspection markets, medical imaging as well as supporting DoD markets in the missile seeker and space based imaging markets. All of these applications will benefit directly from knowledge gained from the STILAPS initiative.

BAKHTAR ASSOC. 3420 VIA OPORTO, SUITE 201 NEWPORT BEACH, CA 92663
Phone: PI: Topic#:	(949) 675-2800 Dr. KHOSROW BAKHTAR AF 01-154 Awarded: 26MAR01
Title:	Performance Assessment of Penetrator Weapons
Abstract:	An innovative and cost-effective technique, based on physical scale-model testing at 1-g, is presented to evaluate the performance of the next generation penetrator missiles designed to take out underground structures. The sub-scale target, an engineered system, can be considered as underground facilities built using tunneling or cut-and-cover construction techniques in a geologic system with variable characteristics. The engineered system can be designed as a complex multi-level facility or simply a system of tunnels excavated at the same depth elevation. The overburden thickness above the potential target can vary from few meters to several tens of meters. The objective of the mission is defined by the launched missile penetrating to a desired depth, detonating or impacting, and producing shock waves impinging on the engineered system (tunnel). The success of the mission is defined by the ability of the penetrator missile to generate ground shocks of large enough magnitude to cause structural damage. Similitude laws are used to determine the relevant characteristics of the scaled-model geologic and engineered systems and those defining size and type of weapons.The proposed study is directed towards the development of an experimental and analytical methods followed by a field test program for performance assessment and design optimization of conventional penetrator weapons used for sure kill. The impingement may occur either side ways or towards the center-line of the underground facility to cause structural damage such as internal spalling of concrete support lining material. Damage assessment is made using the US Air Force EarthRadar.A novel method and cost-effective approach for performance assessment of weapons. Damage assessment for hardened underground structures subjected to penetrator weapons attack. A unique technique for simulating stress wave propagation in anisotropic geologic materials under controlled conditions.

ADVANCED CERAMICS MANUFACTURING 3292 East Hemisphere Loop Tucson, AZ 85706
Phone: PI: Topic#:	(520) 434-6375 Mrs. Marlene Platero-AllRunner AF 01-155 Awarded: 15APR01
Title:	Innovative Methods for Bonding Large Scale Sections of Tungsten Alloys
Abstract:	This program proposes to implement fibrous monolith processing techniques for the manufacturing of large scale tungsten penetrators which incorporate orientation controlled long fiber tungsten filaments bonded with an interface consisting of metal or carbide. It is anticipated that the use of properly controlled orientation of the cellular tungsten material will eliminate impact mushrooming effects and create an adiabatic shearing mechanism for enhanced penetration. High temperature and high pressure Hot Isostatic Processing (HIP) will be used to consolidate actual components. In addition, technology developed and commercialized for fibrous monolith oil and gas drill tool bit inserts used for hard rock drilling will be incorporated into this program.The development of this new fibrous monolith tungsten metal processing technology will allow for low cost production of large and complexed shaped tungsten components with enhanced properties for x-ray shielding and penetrators.

MATERIALS & ELECTROCHEMICAL RESEARCH 7960 S. Kolb Rd. Tucson, AZ 85706
Phone: PI: Topic#:	(520) 574-1980 Dr. Eugene Dyadko AF 01-155 Awarded: 18APR01
Title:	Ductile Intermetallic Joining for Heavy Alloy
Abstract:	Good ballistic performance results when the maximum kinetic energy is delivered to the target. Increasing the weight of the projectile achieves this goal. One reasonable way to enhance the mass behind the nose of the penetrator is to augment its size. The conflict between increased lethality for large projectiles and limited facilities for producing large penetrators leads to a need to join small pieces of heavy alloy into larger projectiles. A copper joint is not strong enough. Nickel bonding would require a high processing temperature, which would cause grain coarsening and lower strength. A better joining method uses an interlayer that reacts to create a ductile intermetallic compound. Good adhesion is achieved during the temperature transient associated with the bonding but the reaction temperature must be held below the eutectic point of the Ni-Fe-W matrix to minimise grain growth. Titanium nickelide, alloyed aluminium nickelide and titanium aluminide have enough tensile strength and ductility to meet the requirements of military projectiles. Corrugating the junction surface area will increase further the strength of the bonding. Using ductile intermetallic compounds as bonding interlayers will lead to strong joints for tungsten heavy alloy parts that will make possible production of full-scale penetrators for military needs, and larger parts for civilian use (radiation shields, gyroscope components etc.)

MILLI SENSOR SYSTEMS & ACTUATORS 93 Border Street West Newton, MA 02465
Phone: PI: Topic#:	(617) 965-4872 Dr. Donato (Dan) Cardarelli AF 01-156 Awarded: 18APR01
Title:	Integrated MEMS Inertial Measurement Unit for Air-Launched Munitions
Abstract:	MEMS integration is proposed as the solution for a miniature Inertial Measurement Unit (IMU) for air-launched munitions in order to satisfy the requirements for low cost, high performance and launch survival capability. An IMU requiring assembly and alignment does not take full advantage of MEMS technologies. Integration also contributes to the IMU performance as the gyros and accelerometers are from a common fabrication technology and related designs. Modeling to achieve optimum performance would be possible. Integration also causes a paradigm shift in that the instrument designer also becomes the IMU designer. The commercial intent is to develop integrated IMUs that can be included in systems that are intuitive to users outside of the guidance community to bolster applications in new areas.The military, industrial and consumer applications for precision motion measurement and control are broad and valuable. These applications span missile guidance, virtual reality simulation & training, oil drilling, vehicle safety and navigation, and personal navigation. OEMs that supply these applications are constrained by the lack of affordable sensors with adequate performance. A low-cost integrated MEMS IMU with tactical-grade performance would enable OEMs to migrate a host of military and industrial products into much larger consumer markets, and to expand the number of applications that deliver economic value based on low-cost precision motion measurement. The resultant economies of scale in production and application would yield significant benefit for the military programs that spawned the enabling technology.

OBRIEN & ASSOC. 406 S. Lane St. Blissfield, MI 49228
Phone: PI: Topic#:	(517) 486-3905 Dr. James M. O'Brien AF 01-156 Awarded: 23APR01
Title:	Microstructure Refinement by Channel Die Pressing
Abstract:	Continued interest in the enhancement of warhead liner performance has led to a number of studies focused on liner material ductility and consistency. Specifically, cold upset forging and annealing have been shown to produce significant grain refinement and texture development in liner plates of various materials. However, in tantalum, and possibly other warhead metals, variations in thermo-mechanical processing among different mills can persist as inconsistencies in the final plate, even following the extensive changes in microstructure occurring in cold forging and subsequent annealing. Equal-channel angular pressing (ECA pressing) is a material conditioning process which by intensive shear deformation is able to produce ultrafine grain sizes, without changing the overall shape of the piece. Application of this process to condition bar stock segments prior to the cold forging of plates could potentially erase any material bias from previous processing and provide for complete uniformity of material properties in forged plates, regardless of the material supplier used. It appears that ECA pressing, followed by cold upset forging and annealing, is the optimum process sequence for the manufacture of warhead liners. This project will apply this sequence to three warhead materials and characterize the results.Successful completion of Phases I and II of this effort will result in a manufacturing sequence for warhead liners which offers improved ductility and consistency over methods used currently.

OPTIMAL SYNTHESIS, INC. 4966 El Camino Real, Suite 108 Los Altos, CA 94022
Phone: PI: Topic#:	(650) 210-8282 Dr. P. K. Menon AF 01-156 Awarded: 03MAY01
Title:	New Adaptive Signal Processing Algorithms for Anti-Jam GPS Navigation
Abstract:	Weapon systems relying on integrated GPS/INS navigation technology are susceptible to jamming from external sources. Anti-jam GPS navigation system can be realized by using spatially separated GPS antennas together with adaptive signal processing technology. The central element of such an anti-jam GPS navigation system is the adaptation algorithm. This proposal advances the development of fast responding, stable, adaptive filter algorithms based on recently developed nonlinear control technology. Adaptation algorithms proposed here can provide convergence guarantees and efficiencies not available in existing algorithms. Phase I research will demonstrate the use of these new adaptation algorithms in the synthesis of anti-jam GPS navigation system using a six degree-of-freedom simulation. Phase I research will also identify the computational requirements for implementing the anti-jam GPS navigation technology. Phase II work will develop a prototype of the anti-jam GPS navigation system using commercial off-the-shelf components. That work will also demonstrate the benefits of combining the anti-jam GPS technology with previously developed guidance-control techniques to develop robust flight control systems for a precision munition. Adaptation algorithms developed under the present research has extensive applications in next generation signal processing systems. Applications include adaptive beam forming in phase-array radars, cellular telephony and video teleconferencing over Internet. Anti-jam GPS technology can provide reliable navigation sensors for the next generation air traffic automation and UAV systems.

POSITRONICS LLC 127 East Gate Dr., Suite 203 Los Alamos, NM 87544
Phone: PI: Topic#:	(505) 661-4949 Dr. Gerald A. Smith AF 01-156 Awarded: 01MAY01
Title:	Long-term Confinement of Dense Positron Plasmas
Abstract:	The objective of this propoosal is to demonstrate the feasibility of storing large numbers of antielectrons, or positrons, for long periods of time. Antimatter has the largest specific energy known to humankind, i.e 180 MJ/microgram. An ordnance package containing micrograms of positrons stored for days would comprise an extremely powerful, lethal and revolutionary weapon. We will investigate several technologies for confining positron plasmas, including Penning traps, linear magnetic mirror traps, and closed magnetic torus traps. Other systems may be considered as work progresses. The deliverable will be a Final Report which includes descriptions of systems, costs and construction details.A low mass system capable of holding hundreds of MJ's of energy for long periods of time has many potential commercial applications. Among these in the aviation sector is a Positron Energy Conversion (PEC) ramjet or turbojmet, with the capability of extended flight (up to 30 days) and range (transcontinental). Applications include weather surveys, population, agriculture and pollution studies, and land and marine assays.

POSITRONICS LLC 127 East Gate Dr., Suite 203 Los Alamos, NM 87544
Phone: PI: Topic#:	(505) 661-4949 Dr. Gerald A. Smith AF 01-156 Awarded: 01MAY01
Title:	Stabilization and Long-term Confinement of Atomic Positronium
Abstract:	The objective of this proposal is to demonstrate the feasibility of storing large numbers of antielectrons, or positons, for long periods of time. Antimatter has the largest specific energy known to humankind, i.e. 180 MJ/microgram. An ordnance package containing micrograms of positrons stored for days would comprise an extremely powerful, lethal and revolutionary weapon. We will investigate techniques for forming and stabilizing atomic positronium, a bound quantum state of an electron and positron. This will include passing a beam of atomic positronium through crossed magnetic and electric fields. We will also investigate technologies for confining large collections of stabilized positronium atoms, including laser levitation and cooling of these atoms. Other technologies may be investigated as work progresses. The deliverable will be a Final Report which includes desriptions of systems, costs and construction details.A low mass system capable of holding hundreds of MJ's of energy for long periods of time has many potential commercial advantages. Among these in the aviation sector is a Positron Energy Conversion (PEC) ramjet or turbojet, with the capability of extended flight (up to 30 days) and range (transcontinental). Applications include weather surveys, population, agriculture and pollution studies, and land and marine assays.

SCIENTIFIC SYSTEMS CO., INC. 500 West Cummings Park, Suite 3000 Woburn, MA 01801
Phone: PI: Topic#:	(781) 933-5355 Dr. Raman Mehra/Ravi Prasanth AF 01-156 Awarded: 21MAY01
Title:	Highly Integrated Control Systems For Smart Munitions
Abstract:	Integrated GPS/INS navigation system is a key component of many guided weapons currently under development. Future weapons systems will integrate heterogeneous components such as actuators and sensors with functionalities such as monitoring, diagnostics, and control to a greater extent. The project's long-term objectives are to identify new challenges arising in this integration and to develop analytical and computational tools to meet them. Phase I demonstrates the design of a fault-tolerant integrated GPS/IMU/Passive EO navigation system for terminal guidance and automatic target recognition. Performance of this hybrid system will be verified in the presence of sensor failures and jamming. Phase I work also develops computational techniques to verify hybrid systems. This work can be seen as laying the foundation for a complete investigation of integration issues and hardware-in-the-loop (HIL) simulations in Phase II. Scientific Systems Company, Inc will be supported by Boeing Phantom Works and Draper Laboratory in all phases of the project.Sensor fusion, fault tolerance, V&V and software certification become pertinent whenever coordination among physical and information processing components are required to achieve reliability and performance in uncertain and dynamic environments. Therefore, the analytical and computational tools we are proposing to develop have direct applications in many areas - MEMS, formation flying, automotive control systems, rendezvous and docking operations in space, telerobotics - to name a few.

SYSTEM DYNAMICS 5346 SW 91st Terrace Gainesville, FL 32608
Phone: PI: Topic#:	(352) 371-8035 Mr. Kevin J. Shortelle AF 01-156 Awarded: 04APR01
Title:	Exploiting Evolutionary Algorithms for Improved Automatic Target Acquistion
Abstract:	The focus of this SBIR Phase I program is to develop and test a feature-based automatic target acquisition (ATA) system exploiting evolutionary algorithm (EA) technology. The ATA system will accept phenomenologically-based target and scene features extracted from high resolution LADAR imagery and output a target classification decision with a high probability of correct classification. The use of LADAR data is particularly attractive since it provides 3D imagery while simultaneously achieving the angular resolution of I2R and range resolution of SAR at a lower cost than either of those two sensors. The EA approach represents an innovative structure for both improving ATA performance and streamlining computations associated with model-based techniques. The approach utilizes proven evolutionary algorithm software that has been developed and successfully implemented on other ATA systems. The results of this research will broaden the technology base of advanced ATA algorithms available to the Air Force as it continues to pursue low-cost, autonomous LADAR seekers for conventional weapons guidance. The performance of the EA classifier will be benchmarked against existing model-based approaches with the metrics being run time, memory requirements, and percent correct/incorrect classification. The automatic vehicle recognition and identification capabilities emanating from this SBIR will have a number of dual-use applications. For instance, the results would be pertinent to aircraft tracking and control at commercial airports, intruder tracking, and intelligent highway applications. Automated systems involving manufacturing inspection (including robotic bin picking) would also benefit from innovative recognition and identification algorithms.

TANNER RESEARCH, INC. 2650 East Foothill Boulevard, Mailstop 100 Pasadena, CA 91107
Phone: PI: Topic#:	(626) 792-3000 Dr. Patrick Shoemaker AF 01-156 Awarded: 13APR01
Title:	Elementary Motion Detection with Contrast Adaptation
Abstract:	Insects display remarkable capabilities for guidance and directed flight based on their visual sense. If duplicated in autonomous flying weapons, these capabilities could greatly enhance their effectiveness. We propose a collaborative effort between an insect neurobiologist and VLSI technologists to develop motion processing theory and technology based on insect vision. This effort will apply new findings from insect neurobiology to the well-established correlational model of the elementary motion detector (EMD), which appears to be the basis for all higher-level visual motion processing in the insect visual system. These new findings suggest that adaptation of contrast sensitivity, mediated by motion, plays a crucial role in extending the dynamic range of motion estimation and conferring response invariance with respect to non-motion-related parameters. Thus, we propose an effort to formalize this theory and further develop an implementation approach for an EMD in analog VLSI to include the capability for contrast adaptation.Estimation of egomotion and tracking of small moving targets are two capabilities of insect visual motion processing that would be directly useful for autonomous flying vehicles and weapons. Expected applications are in guidance for near-ground flight and in seeker technology.

TANNER RESEARCH, INC. 2650 East Foothill Boulevard, Mailstop 100 Pasadena, CA 91107
Phone: PI: Topic#:	(626) 792-3000 Dr. Thomas J. Bartolac AF 01-156 Awarded: 19APR01
Title:	Advanced Algorithms for Point Target Detection
Abstract:	New developments in neuromorphic concepts permit massively parallel signal processing co-located with the cryogenic focal plane detector array. The Wave Process is a low-contrast moving point target detection algorithm that is efficiently implemented in a compact analog VLSI circuit. It reduces the data rate to downstream sensor processing, while providing data with a higher density of target information than the scene as a whole, resulting in smaller, lighter sensors with improved mission performance. Tanner Research proposes to dramatically increase the Wave Process signal/noise by adding Elementary Motion Detection as a pre-processing function. We will also make major improvements in Wave Process detection of stealth targets by adding Optical Flow and shape-finding post-processing functions. In Phase I, Tanner Research will develop and demonstrate these extensions to the Wave Process algorithm, using an existing high-fidelity simulation and validated imagery data sets representing scenarios relevant to AFRL. We will quantify the improved target detection capability, and establish goals and approaches for the Phase II effort. Compact, low-cost, high performance sensors for point target detection will provide new space-based surveillance capabilities, reliable cruise missile detection, advanced miniature seekers, and collision avoidance for manned and unmanned aircraft. We will pursue technology insertion opportunities with existing sensor platform and seeker primes.

WINTEC, INC. 220 Eglin Parkway SE, Suite 4 Fort Walton Beach, FL 32548
Phone: PI: Topic#:	(850) 664-6203 Mr. Fred Benedick AF 01-156 Awarded: 26MAR01
Title:	Munitions Research
Abstract:	The MIL-STD-1760 aircraft /store electrical interface standard significantly reduced the cost of electrically integrating smart stores on aircraft and dramatically enhanced aircraft/store interoperability. An evolving electrical interface standard is expected to achieve similar results for integration of planned miniature stores on advanced carriage dispensers. Though these two standards deal with some lower level software interface issues (primarily related to communications), there is little existing commonality in application level aircraft/store software interfaces. Since some government estimates attribute approximately 40 percent of the non-recurring cost of an aircraft/store integration effort to software development, substantial additional savings could be achieved through enhanced commonality and standardization in these application level interfaces. In fact, better standardization in aircraft/store software including the incorporation of such commercial techniques as plug and play capabilities was specifically pointed out as highly desirable by a 1999 NATO Industrial Advisory Group (NIAG) study of potential improvements in Aircraft, Launcher, and Weapon Interoperability (ALWI). The proposed effort would investigate requirements for aircraft/miniature store software standardization, define an open system software integration framework, develop a concept for a real world example application, and develop a plan for a follow-on prototyping/demonstration program. The technology provided by this program will provide a basis for significantly reducing aircraft/miniature store (and other store) software integration costs and enhancing interoperability. It has significant potential commercial applicability in robotic vehicle and home and office automation applications.

COHERENT TECHNOLOGIES, INC. 655 Aspen Ridge Drive Lafayette, CO 80026
Phone: PI: Topic#:	(303) 604-2000 Dr. Wayne S. Pelouch AF 01-157 Awarded: 04JUN01
Title:	Compact Monolithic Waveguide LADAR Munitions Seeker
Abstract:	The goal for the next-generation laser transmitter for high-energy single-pulse LADAR seekers is to reduce size, cost, weight, and complexity, while increasing robustness and operational lifetime. Current laser transmitters (1) contain numerous free-space optical components that limits the robustness and (2) are limited by thermal problems such as heat removal and temperature control. Coherent Technologies, Inc. (CTI) proposes to develop a novel compact monolithic eyesafe Er-doped 1.6-micron laser that can be assembled with permanent optical alignment. The transmitter architecture is based on a novel waveguide laser design that has significant advantages over bulk laser designs. Key transmitter features are (1) compact high-efficiency laser diode pumping with simple and low cost coupling optics, (2) unique design of the Er-doped laser transmitter results in excellent thermal management for a longer operational lifetime, and (3) intrinsic laser material properties allow operation over wide ambient temperature range. The transmitter is capable of >100 mJ output energy in a <5 ns pulsewidth, with a final cost estimate (in quantity) of less than $2000 per transmitter. CTI's proven ability to design and engineer rugged and compact laser ranging systems for demanding environments will ensure a successful overall development program. Anticipated applications include (1) Laser seeker transmitters for multiple platforms, (2) Low cost transmitters for other eyesafe laser remote sensing applications, (3) Laser sources for commercial markets such as materials processing, medical, and instrumentation.

Q PEAK, INC. 135 South Road Bedford, MA 01730
Phone: PI: Topic#:	(781) 275-9535 Dr. Kevin F. Wall AF 01-157 Awarded: 01APR01
Title:	High-energy, eyesafe transmitter for LADAR
Abstract:	The most widely used solid state laser technology is based on Nd-doped laser materials, providing output in the 1050-1060-nm wavelength region. Alternative laser materials can provide other wavelengths more suited for eyesafe LADAR, but systems using these materials have shown substantial limitations in either or both power output and efficiency. For focal-plane-array (FPA)-based LADAR systems in particular, the need to generate a combination of high energies and short pulses eliminates many solid state lasers from consideration. In the work proposed here, we take advantage of recent developments in solid state laser design, new laser materials and improved high-power semiconductor lasers to develop an efficient, compact, high-power laser system in the 2050-2100-nm wavelength region. The wavelengths generated are eyesafe, fall in an atmospheric window and are readily detectable with existing FPA technology. The proposed laser design uses a minimal number of diodes to generate high-energy pulses, consistent with the desire for a compact and low-cost system, and the use of conduction cooling throughout leads to flexibility in thermal management.The laser to be developed in this proposed effort would have a unique combination of power output and wavelength and could open up new capabilities for materials processing systems, particularly for materials with a high water content. Another application of laser could be in the area of laser medicine, for surgical applications in tissue cutting, coagulation or welding. Finally, the laser can be also used as part of an industrial gas sensing system for detection of minute quantities of water vapor or carbon dioxide.

KAZAK COMPOSITES, INC. 32 Cummings Park Woburn, MA 01801
Phone: PI: Topic#:	(781) 932-5667 Dr. Jerome Fanucci AF 01-158 Awarded: 18MAY01
Title:	Design, Fabrication and Testing of Low Cost Composite and Metal/Composite Hybrid Lattice Fins
Abstract:	KaZaK Composites and our program partner, Raytheon Missile Systems, propose to investigate the design, low cost manufacture and testing of several material and process alternatives for making a less costly replacement for a current baseline EDM-fabricated stainless steel lattice fin. KCI's current leading candidate, an all-graphite/epoxy fin, when combined with our expected low cost production process, should result in a minimum 90% cost reduction compared to the $2,000 baseline fin price. In addition to the all-composite design, we will also consider hybrid systems that combine a composite lattice with a metal base, and improved systems for making all-metal fins. Because the stated application is subsonic rather than supersonic, high temperature issues that may have precluded low cost metal production technology might be applied to reduce the cost of the low speed metal designs. During Phase I KCI will fabricate several prototype lattice fin prototypes and subject them to static load testing. We also will perform full scale dynamic pressure deployment tests using a water tunnel during Phase I. Working with Raytheon, we will project the synergistic weight and cost reduction that a lighter lattice fin might generate in a resized missile control actuation system. RCS reduction considerations are driving aircraft armament toward internal stores requirements. This will necessitate the development of smaller weapons without a reduction in capability. The lattice fin is a technology that helps this evolution by both creating a tighter package size, and by reducing the requirements on the control actuation system, allowing that to become smaller as well. Cost has been one of the impediments to the general acceptance of lattice fin technology in the US. Successful completion of the proposed Phase I and II work should create a cost effective solution for manufacturing the lattice fin structure. Once proven, it is expected that the market for weapons making use of this technology will grow quickly as new, smaller, smarter, more capable weapons are purchased to supply the more stealthy aircraft, designed for internal weapons carriage that will be entering the fleet.

MATERIALS & ELECTROCHEMICAL RESEARCH 7960 S. Kolb Rd. Tucson, AZ 85706
Phone: PI: Topic#:	(520) 574-1980 Dr. Lev Tuchinskiy AF 01-158 Awarded: 27APR01
Title:	Novel Fabrication Technology For Lattice Fins
Abstract:	The nature of lattice fins allows them to be folded close to the weapon's structure when not deployed. That opens up the way for internal ordnance carriage, which leads to the reduction of both flow field drag and radar detection. The high cost of lattice fin fabrication remains an issue. The current manufacturing process results in a per fin cost of roughly $2000. This Small Business Innovation Research Phase I project demonstrates a novel alternative waste-free process for fabrication of lightweight lattice fins, which enables 12-17 times reduction a cost per fin. The proposed approach allows fabrication of net-shape fins of different web geometries (including very thin webs), use of different materials: metals, alloys, reinforced plastics, composites. The process will be developed for stainless steel and composite lattice fins with different web thickness. Various candidate materials, including composites that could be viable fin materials will be evaluated and the cost savings associated with the utilization of the most affordable materials and production process will be established.It is anticipated that this Phase I program will result in the smallest, lightest lattice fin assemblies possible, consistent with the structural demands of the maneuvering weapon airframe. Viable material and manufacturing process advocated in a proposal will be equally applicable to the production of efficient lattice fins for a 250-pound class munition, a 2000-lb munition, or any weight class in between. Commercial application includes lightweight metal sandwich panels for vehicle energy absorbing components, automotive interiors, etc.

MARK FOLSOM, CONSULTING ENGINEER 25747 Carmel Knolls Drive Carmel, CA 93923
Phone: PI: Topic#:	(831) 626-8252 Mr. Mark Folsom AF 01-160 Awarded: 13JUN01
Title:	Micro Electro Mechanical System (MEMS) Scale Deposited Energetic
Abstract:	The description and characterization of a novel, low firing energy, semiconductor based, scaleable monolithic electro-explosive device (EED) is presented. The structure employs laminations of thin layers of metallic and nonmetallic elements or inorganic compounds that react exothermically under suitable excitation. The laminations can be selectively deposited in the shape of a bridge to form a bowtie-shaped igniter. This structure produces a thermal output that can jump an airgap in excess of 100 mils and initiate powder, making it possible to employ mechanical shutters for safing. The laminations can also be used to coat the inside of a micro-machined cavity. The micro-machined cavity with the laminated material can thereby act as a miniature shaped-charge. The focused plasma and particle output of the shaped charge can be used for a variety of purposes such as perforating a thin metal foil. The structures can fabricated with conventional microelectronic techniques which allow for very economical manufacturing. The proposed devices will provide more vigorous output than conventional semiconductor bridge initiators without a penalty in cost or safety. These devices promise to provide safer more reliable initiation for blasting, automotive airbags, tactical weapon systems and aerospace ordnance devices.

FREESTYLE TECHNOLOGIES, INC. 4152 Aldrich Avenue South Minneapolis, MN 55409
Phone: PI: Topic#:	(612) 823-7734 Dr. Kevin S. Schweiker AF 01-161 Awarded: 11APR01
Title:	Novel LADAR Signature Exploitation for Obscured Target Environments
Abstract:	Laser radars (ladars) have been investigated for the detection, classification and terminal tracking of military targets. One area of concern is the performance of automatic target acquisition (ATA) algorithms on targets that are stochastically obscured by foliage. A program is proposed that will increase the understanding of target obscuration while increasing the set of non-proprietary ATA algorithms available to the weapon systems designer.The techniques developed during this program will benefit the field of computer vision. Specifically, robots that pick parts and perform quality control will be enhanced by the ability to effectively process occluded objects. Medical imaging will also benefit from the algotihms developed during this program.

ENIG ASSOC., INC. 12501 Prosperity Drive, Suite 340 Silver Spring, MD 20904
Phone: PI: Topic#:	(301) 680-8600 Dr. D. John Pastine AF 01-166 Awarded: 29MAR01
Title:	Use of RF Emissions from Chemical Explosions for BDI/BDA of Attacks on Underground Hard Targets
Abstract:	A method is proposed for distinguishing between explosive detonations in air, underground, and in underground chambers, and for estimating the chamber size by analyzing the electromagnetic signatures at a distance from each of these points of detonation. The method is an extension of a previous theoretical model developed at Enig Associates, Inc., which explains how the electromagnetic signals are related to the electric charge generated by the thermohydrodynamic states of the detonation products "fire ball." These signals have been measured for many years by different observers, but no previous rational theoretical model had been developed to explain how they came about. With our augmented radiation computer code, we expect to carry out a series of computations for the theoretical radiant power output for the types of detonations described above. Further code computations will compare the radiant power output from different explosives for fixed geometrical configurations. Because the radiation is related to the ionization within a fire ball, and the ionization depends sensitively on the temperature, the need for accurate temperature equations of state of the products is imperative, and we intend to use our own specialized, published equations of state for these calculations. In addition to the radiation predicted by our theory, the normal thermal RF output will be calculated. Damage assessment with a passive system at a distance from target explosion; to counter terrorists and hostile forces; to detect sources of weapons fire; increase safety in building demolition and land clearance

OPTISWITCH TECHNOLOGY CORP. 6355 Nancy Ridge Drive San Diego, CA 92121
Phone: PI: Topic#:	(858) 452-8787 Dr. David Giorgi AF 01-168 Awarded: 23MAR01
Title:	Optically Activated Switch for Pulsed Power Applications
Abstract:	OTC proposes the development of a high power optically activated solid-state switch for the enhancement of current pulse power and power electronic systems. The switch is packaged into 100kV/100kA modules with a rise-time of <10ns. The switch is fabricated by direct contacting (wafer bonding or alloying) of multiple thyristor elements in series, a technique which would offer the opportunity of both a high degree of compactness (low inductance) as well as manufacturability. The optical switching results in ultra-low jitter (ps) between switch modules and enables series and parallel configurations for mega-ampere and mega-voltage applications. This advanced switch technology makes feasible more reliable, compact and less costly, pulsed power systems, based entirely on solid-state switching technology.The development of this advanced solid state switch will enable high peak power systems to utilize semiconductor switching. This will make them more reliable, and less costly to build and maintain. Commercial applications are numerous; some include protecting electric utility and telecommunication systems from high current surges caused by lightning strikes and switching transients.

STERLING SEMICONDUCTOR, INC. 22660 Executive Drive, Suite 101 Sterling, VA 20166
Phone: PI: Topic#:	(703) 834-7535 Dr. Larry B. Rowland AF 01-169 Awarded: 02APR01
Title:	High Efficiency High Voltage 4H-SiC Devices
Abstract:	In response to the Air Force SBIR topic AF01-169, Sterling Semiconductor proposes a 6-month, $100K program to establish the feasibility of the materials technology necessary for growth of complex, thick (> 100 mm), highly pure silicon carbide (SiC) device structures in a single growth run. Growth of complex device structures in a single run will greatly reduce the cost of SiC epitaxial growth over existing SiC epitaxial technology by improving yield and throughput. The capability to grow these complex pnpn or npn structures without growth interruption will also have system impact by dramatically improving performance of SiC power devices. These improvements, when combined with Sterling's leadership in SiC wafer technology, will enable the high-yield manufacturing of 5kV switching devices with high switching speed and low on-resistance. Sterling will utilize this technology during Phase I to produce a 5 kV/10A inverter using 4H-SiC rectifiers and Si switching devices Future power systems, as envisioned by the Department of Defense (DoD), will require lighweight, high-density power converters (>1 MW) for operation at high temperature in hostile enviornments. Active devices with high-voltage (25kV-100kV) and high-current (50A-1000A) capability are required for such power converters.

ECLIPSE ENERGY SYSTEMS, INC. 2345 Anvil Street North St. Petersburg, FL 33710
Phone: PI: Topic#:	(727) 344-7300 Dr. Nicolai Kislov AF 01-170 Awarded: 21APR01
Title:	Stabilization of Phased Focus Array Using Electrochromic Technology
Abstract:	Significant modulation of solar reflectance, solar absorption, and IR emissivity can be achieved with electrochromic devices operating at very low voltages. They use very little energy and can maintain their state of reflectance, absorption, and emissivity for some time after the potential has been removed. Devices fabricated as a monolithic stack of solid state inorganic materials can withstand the harsh space environment. These kinds of Variable Electrochromic Devices (VEDs), with no moving parts, are well suited for active thermal control of spacecraft and deployable aerospace membrane structures. The Phase I effort will produce 100cm2 VEDs on thin polyimid films with an areal density of 7g/m2 and modulations of emittance from 0.1 to 0.5 and solar absorptance from 0.2 to 0.8. The optical, thermal, and electrical performance of these devices will be characterized. A detailed calculation will be performed to predict thermal performance of these electrochromic coatings. In Phase II of this effort, samples of the electrochromic devices will be tested to determine their tolerance to high vacuum, UV light, and bombardment with energetic oxygen ions. The design will be optimized to improve performance, reliability, and durability in the space environment. AEROSPACE � Standardized VEM thermal management devices will be developed for use in a variety of spacecraft. They will be deposited on flexible polyimide substrates suited for application to both flat and curved surfaces. � Very large area ultra-thin VEM devices will be developed for solar sail applications. � Special variable solar thrust panels will be developed to dampen vibrations within large gossamer space structures. VEM thermal management systems will be developed for dimensional stabilization of gossamer and rigid aerospace structures. ARCHITECTURAL GLAZING � VEMs will be integrated into insulated glass units to improve the energy efficiency in architectural applications. � Vems will be embedded in translucent fiberglass panes to improve the energy efficiency in industrial and commercial applications. 8.3 AUTOMOTIVE GLAZING � VEMs will be applied to the inside of automotive windows and sun roofs to improve the security and energy efficiency of the vehicles.

IMPACT TECHNOLOGIES, LLC 125 Tech Park Drive Rochester, NY 14623
Phone: PI: Topic#:	(716) 424-1990 Dr. Michael J. Roemer AF 01-171 Awarded: 23MAR01
Title:	Prognosis/Diagnostics for improved Gas Turbine Engine reliability and maintainability
Abstract:	Impact Technologies, in cooperation with GE Aircraft Engines, Pratt & Whitney and Spectro Inc., propose the development, implementation and validation of diagnostic and prognostic (D&P) technologies specifically designed for real-time, automated health assessment of oil-wetted components in gas turbine engines. Various corroborating D&P technologies from different engineering disciplines, including oil analysis, vibration analysis and rotordynamic modeling, will be integrated together under this program using automated reasoning and intelligent data fusion algorithms. With a combination of health monitoring data and model-based techniques, a comprehensive component prognostic capability can be achieved throughout a components life, using model-based estimates when no diagnostic indicators are present and monitored features such as oil debris and vibration at later stages when failure indications are detectable. Only through the utilization of all of these sources of engineering information can up-to-date assessments and predictions of component remaining useful life be determined for use in automated maintenance and logistics systems. The oil-wetted component prognostic modules will be calibrated and verified using GE F110-129 component failure data, PTO shaft and bearing data from a GE F404 engine and gearbox seeded fault and accelerated failure data. In addition, in-service data from the GE F110-129 and Rolls Royce F405 engines will be used to develop and verify the data/knowledge fusion strategies under degraded conditions. The gas turbine engine component prognostic modules will be capable of integrating real-time information from multiple sources on the engine so that critical engine component diagnoses and prognoses can be made more confidently and at an earlier stage. Costly inspection routines and premature component replacements can also be avoided using the prognostic technologies developed under this program. Commercial applications for the prognostic and diagnostic strategies developed can be realized on any machinery health monitoring application in the electrical generation industries, chemical processing industries, commercial aviation as well as gas transmission and oil industries.

LONG ELECTROMAGNETICS, INC. 44 Terraceview Mt. Lebanon, PA 15243
Phone: PI: Topic#:	(412) 462-9877 Mr. Lawrence J. Long AF 01-172 Awarded: 03APR01
Title:	Actively Cooled Power Converter Technology
Abstract:	Emerging high power airborne weapon systems will require multi-megawatt electrical power at voltages approaching 100 kV. Although multi-megawatt airborne generators are currently under development, they will not be able to directly generate the very high voltage(s) needed for some weapon systems. Power converter system development, in the past, has typically focused on power electronics but the power converter system in new systems will also require a high power step-up transformer to convert the relatively low generator voltage to higher voltages. The weight and losses of the transformer can easily dominate the design of the power conditioning system. Large commercial transformers are typically oil-filled, air-cooled, relatively heavy and designed for operation groundbased systems operating in one atmosphere of pressure. This program will develop a lightweight, high voltage, multi-megawatt transformer specifically designed for proposed airborne power and cooling systems. Design options will include both cryogenic and non-cryogenic transformers with integral power conditioning and cooling system, specifically designed to operate in airborne systems.This program will develop and test a novel lightweight, high voltage transformer with integral cooling system. Immediate applications will be for high power military systems, but the design principles developed in this program will make their way into commercial applications, such as electric utility facilities in high population areas where minimizing equipment size is important and conventional transformer air cooling systems are difficult.

LONG ELECTROMAGNETICS, INC. 44 Terraceview Mt. Lebanon, PA 15243
Phone: PI: Topic#:	(412) 462-9877 Mr. Lawrence J. Long AF 01-173 Awarded: 06APR01
Title:	Cryogenic Electrical Machines
Abstract:	Lightweight cryogenic generators, made with advanced high temperature conductors will be needed to meet the demands for lightweight multi-megawatt electrical power in emerging high power airborne weapon systems. This program extends the HTS work done in previous programs, and will build and test a one-megawatt HTS generator using novel design concepts that will provide a full size high speed HTS generator suitable for emerging airborne weapon systems. The generator is designed to serve as a fully functional megawatt-class generator for early groundbased power system demonstrators. Additionally, the simplicity and low cost of this design allow it to function as a long term test facility with which new HTS conductors, cryogenic cooing systems and generator components can be easily (and inexpensively) retrofitted and tested under realistic operating conditions. This HTS generator is designed with easily replaceable rotor coil modules and is designed for easy substitution of complete stator windings; allowing the generator to produce a variety of output voltages, required by different airborne systems.This program will develop and test a low cost, high power, superconducting generator has been simplified to reduce the cost and increase the reliability of these machines. Immediate application will be for high power military systems, but the design principles developed in this program will make their way into commercial application, facilitated by the availability of the fully functional generator test facility developed in this program.

EIKOS, INC. 2 Master Drive Franklin, MA 02038
Phone: PI: Topic#:	(508) 528-0300 Mr. Paul Glatkowsi AF 01-174 Awarded: 23MAR01
Title:	High Energy Density Dielectrics for Pulse Power Capacitors
Abstract:	Eikos Inc. proposes to develop high dielectric constant (K), low loss nanocomposite polymers to meet the design objectives of high energy density (HED) capacitors. In the proposed Phase I program, we will apply rigorous computational techniques to predict the properties of this new class of nanocomposites. We will compound nanocomposite resins, fabricate films for testing, and measure the electrical properties. Initial calculations and testing indicate that these polymers will have better dielectric properties than analogous polymers lacking nanotubes. The development of nanocomposite materials is crucial to overcoming the current plateau in dielectric materials development. This technology lends its self to application and enhancement of existing polymer and ceramic dielectric materials. The development of high dielectric constant, low loss dielectrics will have immediate application in meeting the needs for high energy density capacitors.The compact, high temperature and high-energy density DLC capacitors have myriad uses in both commercial and military applications. These include applications such as domestic utilities and appliances, well drilling equipment, power supplies, aircraft, satellites, trains, automobiles and medical devices. The high temperature capability of the capacitors will enable electronic devices to be mounted close to aircraft engines. This enables more sophisticated engine actuators, sensors and controls to be implemented with a net reduction in weight achieved through the reduction or even elimination of wiring hardware, which is necessary when the electronics have to be remotely located. High-energy density capacitors are also greatly needed for Air Force and Army pulse power applications. Eikos has already started negotiations with venture capital firm for securing financing for commercialization of this promising technology.

THERMAL MANAGEMENT & MATERIALS TECH 4664 Vista de la Tierra Del Mar, CA 92014
Phone: PI: Topic#:	(619) 665-2348 Dr. Daniel L. Vrable AF 01-175 Awarded: 09MAR01
Title:	High Power Microwave Source Cooling to Enable Compact Directed Energy Weapons
Abstract:	An innovative lightweight thermal management concept providing high heat flux capability for High Power Microwave (HPM) beam collectors or beam dumps for Directed Energy Weapon Systems is proposed. Major obstacles to the practical application of DE Weapons for aircraft require effective solutions in thermal management and reducing the mass of the components. The beam collector/dump handles the majority of the thermal load and represents a major thermal management challenge. The proposed thermal approach utilizes enhanced cooling mechanisms (subcooled nucleate flow boiling and jet-impingement cooling) coupled with advanced high thermal conductivity materials and optimized cooling channel geometry. The concept provides both improved thermal performance and reduces the beam collector mass by 30-50 per cent over current designs. The enhanced heat transfer and lower temperature gradients through the structure (due to improved thermal conductivity and thinner walls) allows much higher heat flux operation yet maintains the collector's structural temperatures. The overall design concept provides a mass efficient and highly effective thermal control approach that can be fully integrated with the aircraft cooling system.The lightweight and high heat flux structure will have immediate application for HPM and High Energy Laser (HEL) Directed Energy Weapon Systems. High system payoffs include higher heat flux operation, reduced component mass, lower temperatures and improved structural integrity of the components. The technology can be applied to other high heat flux applications including: power devices, advanced avionics, electric vehicles and high performance super computers.

SYNCHRONY, INC. 6410 Commonwealth Dr. Roanoke, VA 24018
Phone: PI: Topic#:	(540) 989-1541 Dr. Victor Iannello AF 01-176 Awarded: 23MAR01
Title:	Oil-Free Bearings for Mid-Size Uninhabited Air Vehicle Gas Turbine Engines
Abstract:	An innovative magnetic bearing system for UAVs and other gas turbine engine propulsion systems is proposed. The magnetic bearing system features a novel digital controller that reduces the size, weight, vulnerability, and cost while improving performance and reliability. In Phase I, the concept will be built and demonstrated with proof-of-concept tests. In Phase II, a prototype will be built and demonstrated at protoypical engine conditions.industrial engines, marine engines, aircraft propulsion, electric power production

EIC LABORATORIES, INC. 111 Downey Street Norwood, MA 02062
Phone: PI: Topic#:	(781) 769-9450 Dr. Stuart F. Cogan AF 01-177 Awarded: 24MAR01
Title:	Autonomous Electrochemical Power Source with Wireless Communication for MEMS Devices
Abstract:	The development of a battery-based power source for MEMS devices in nano and microsatellites is proposed. The power source combines a thin-film battery and supercapacitor in a configuration suitable for both continuous low power and pulsed power applications. The power source will be controlled and recharged through a wireless communications link that also controls the MEMS device and allows downloading of data acquired by MEMS-based sensors during autonomous operation. The Phase I program will demonstrate the fabrication of the battery and supercapacitor in a form suitable for interconnection with MEMS devices. An RF-telemetry based interface to the power source will be designed and used to establish thin-film antenna geometries, recharge rates and bandwidth for data transmission. The design will determine the performance envelope of the power source and communications link and identify applications for Phase II development. In Phase II, fully integrated MEMS devices that operate autonomously with the proposed power source will be fabricated and tested. An end-user will be identified to act as a test-bed for the devices in an Air Force application and provide a near-term commercial opportunity.MEMS devices have significant commercial potential for stress and acceleration measurement in the aerospace industry. MEMS applications in chemical sensing, microanalysis, and miniature machinery are emerging. The availability of an equally small power source with wireless communication is essential to the successful implementation of MEMS in many of these applications. As such, there appears to be major commercial potential for the proposed power source in MEMS applications as well as non-MEMS applications in medical devices, wireless testing, and in any application requiring a small autonomous power source.

ELECTRODYNAMICS ASSOC., INC. 409 Eastbridge Drive Oviedo, FL 32765
Phone: PI: Topic#:	(407) 977-1825 Mr. Jay Vaidya AF 01-178 Awarded: 21MAR01
Title:	High Power Generators for Optimized Integrated DEW Power Systems
Abstract:	This proposal addresses issues relating to the application of non-superconducting generators in 1 to 5 MW range to high voltage Directed Energy Weapon (DEW) systems. The main focus is to select the best condidate generator from a variety of electromagnetic and electrostatic generator concepts. The selection of the optimum generator concept must however be based on the parameters relating to the entire generating system including the turbine, the electronic power conditioning, and the DEW load. The selection parameters for optimization are: power density, efficiency, fuel consumption, and reliability. With a view to satisfy the need to review the entire system, we have teamed with Rolls Royce, Hamilton Sundstrand and Lockheed Martin. The work plan includes evaluation of various generator and power electronics approaches and study of the integrated overall system in terms of thermal and cooling issues, fuel consumption. Internal and external technical resource have been pooled to address electrical, electronics, structural, dynamic, and thermal issues. We expect to select an optimized generator/controller configuration that is likely to compare favorably with superconducting generator approach on the basis of the integrated system parameters. A detailed design analysis of the selected configuration will be presented. This will form the basis for fabrication of hardware for demonstration during Phase II.High voltage DEW generators in the 1 to 5 MW range are applicable to air, space ground, and water based systems in Air Force, Army and Navy components of the DoD. In addition to the DEW loads, the generators will also provide power for Electromagnetic guns. In the commercial field, applications in Distributed Power Systems will be met because of the high power density and high fuel efficiency although the high voltage will not be the critical issue.

INNOVATIVE POWER SOLUTIONS, LLC PO Box 730 Oakhurst, NJ 07755
Phone: PI: Topic#:	(732) 493-3680 Mr. Scott Jacobs AF 01-178 Awarded: 23MAR01
Title:	Advanced Electrical Power Generation (High Power Non-Super-Conducting)
Abstract:	Weapon systems of the directed energy type require high electric power. A laser based system will require several Megawatts, usually at low duty-cycle. Another technology is using microwave energy, which requires continuous power of several hundreds Kilowatts. The technical challenge is to develop a lightweight, compact power system that will be designed to operate on aircraft operating from sea level to 20,000 feet. Power considerations for this design will be up to 5 Megawatts, and several duty cycles will be evaluated for an array of potential applications. The opportunity in this program is to develop a conventional generator system, which will favorably compete with super-conducting systems both in terms of size and weight, while being less complicated and significantly less expensive. A generator that will have continuous output of 600-700 kW, to support a microwave based directed energy system, could provide power bursts of up to 1.5 MW and support a laser system. This will allow for a single power source for both applications. An application of this technology could be a current Lockheed-Martin program that requires an output of 1.5MW at 270 VDC, and load duty cycle of 5 seconds "ON", followed by 10 seconds "OFF" repeated 7 times. Potential use as in-flight power source for directed energy loads. May pertain to military and commercial ground and ground mobile/transportable power systems for standby and emergency power. Emergency power for hospitals, telephone companies,and other industries

INNOVATIVE SCIENTIFIC SOLUTIONS, INC. 2766 Indian Ripple Rd Dayton, OH 45440
Phone: PI: Topic#:	(937) 252-2706 Mr. Dennis Grosjean AF 01-179 Awarded: 10APR01
Title:	Condition Monitoring of Aircraft and Ground-Support Subsystems
Abstract:	An effort to apply condition-monitoring techniques to aircraft and ground-support equipment is proposed. Initially, the Phase I effort will concentrate on demonstrating the use of motor-current analysis to determine mechanical anomalies in motor-driven systems. A practical instrument will then be designed for field- and depot-level use on the Predator tail-servo system. The Phase I effort also will include a study of and recommendations for applications of motor-based, acoustic, chemical, thermal, and optical method--separately or in synergistic combination--for condition monitoring of other systems in the Air Force inventory. A Phase-II effort will involve construction of the condition-monitoring instrument designed in Phase I and application of the results of the Phase-I study. The Phase-III effort will apply condition-monitoring methods to critical industrial systems where downtime is very costly.The overall goal of this program is the development of commercially available, cost-effective instruments capable of determining the fitness of aerospace electrical and mechanical systems under actual operating conditions. The motor-based methods will have applications to a wide variety of aerospace and industrial systems where mechanical energy is provided by electric motors. The synergistic combination of several methods will be cost effective in numerous high-value applications where safety and reliability are critical.

METACOMP TECHNOLOGIES, INC. 650 Hampshire Road, Suite 200 Westlake Village, CA 91361
Phone: PI: Topic#:	(805) 371-8756 Sampath Palaniswamy AF 01-179 Awarded: 30MAY01
Title:	Aero Propulsion and Power Technology
Abstract:	Metacomp Technologies, Inc. proposes to develop an innovative computational design technology aimed at enhancing combustor efficiency. Using the advanced simulation tool CFD++, developed through partial SBIR funding from Wright Labs, the dynamical interaction among acoustics, flow unsteadiness, combustion and turbulence in combustors will be studied. This will lead to the level of understanding of the parameters affecting combustor performance necessary to build the design technology. Key elements in the proposed design tool are based on cutting edge technologies developed by Metacomp such as LNS (Limited Numerical Scales, a hybrid RANS/LES model), SRRR (Sub-scale Resolution using Recursive Reconstruction) and SGR (Scale Generation through Redistribution). LNS enables LES (Large Eddy Simulation) on relatively coarse meshes, SRRR and SGR work in tandem to model turbulence/chemistry interactions. Coupled with high-order accuracy and dual-time stepping, these methodologies enable high fidelity simulation of unsteady, turbulent reacting flows, including acoustic oscillations, typical of combustor flows.This effort will impact the design of high performance combustors, leading to improved efficiency of both military and commercial engines. Critical parameters affecting combustor performance will be isolated, leading to a database necessary for design optimization. The resulting design tool can be utilized in diverse areas from military aircraft engines through commercial jet power plants to power generators and incinerators.

MIDE TECHNOLOGY CORP. 56 Rogers Street Cambridge, MA 02142
Phone: PI: Topic#:	(617) 252-0660 Dr. B.P. Masters AF 01-179 Awarded: 23MAR01
Title:	Aero Propulsion and Power Technology
Abstract:	The proposed innovation is a High-bandwidth, Efficient, fuel Flow Actuator (HEFA). The design stems from a systems perspective, including power electronics, mass & volumetrically efficient driving mechanism, preferential failure modes, and thermally tolerant operation. Our solution leverages innovations in flow, mechanical packaging, electromechanical and power transfer efficiency to yield a robust performance device for combustion control. The actuator targets the problem of pressure fluctuations in aircraft engines. Specifically, it focuses on eliminating pressure fluctuations through high bandwidth modulation of the fuel. The results of controlling unwanted fluctuations are reduced high cycle fatigue (improved lifetime and reliability), improved combustion efficiency, and potentially reduced pollutant emissionsThe proposed solution will directly benefit DoD programs to control pressure oscillations in high performance engines such as those slated for future fighter aircraft. Furthermore, as a major manufacturer of aircraft engines and ground based gas turbines, General Electric views the development of systems and techniques for suppressing and/or eliminating the pressure oscillations, which are inherent to all gas turbine combustion systems, as important to the reduction of engine development and operation costs.

PYRODYNE, INC. 11280 Panorama Drive New Market, MD 21774
Phone: PI: Topic#:	(301) 607-6108 Dr. Frederick S. Billig AF 01-179 Awarded: 22MAR01
Title:	Streamline Traced Inlets for High Speed Applications
Abstract:	This SBIR will use an innovative technique to develop the designs of a large class of inlets for use in Single-Stage-To-Orbit, SSTO and Two-Stage-To-Orbit, TSTO transatmospheric accelerators, global reach- high-speed aircraft and long-range missiles. The genera of the designs are Busemann inward turning flowfields. Streamline traces are carved from these flowfields to form the compression surfaces of a broad variety of practical inlet geometries. These surfaces are then truncated to provide an optimum balance between component weight and inlet compression efficiency. All of the inlets have highly swept leading edges, which minimizes their drag and the corresponding thermal loads. A major part of the effort will be the development of novel techniques to enable starting. The Phase I effort will include the design of sets of interactactive jets produced by a gas generator that will be used to aerodynamically deflect a portion of the inlet compression fields. Documentation of the inlet performance and demonstration of the starting devices will be a major part of the Phase II effort.The principal tangible product of this SBIR will be the design and development of the starting device for streamlined-traced inward-turning inlets for SSTO and TSTO transatmospheric accelerators, long range high speed cruise aircraft and missiles. Both military and commercial customers are anticipated for the space access vehicle and cruise aircraft. Two major aerospace companies have reviewed and strongly endorsed this SBIR Proposal. Both companies will closely follow the progress of the Phase I effort for consideration of becoming Fast Track sponsors of a Phase II effort. Marketing of the inlet starting device will be initiated during the Phase II Program and the capitalization effort of PYRODYNE for Phase III and beyond with be initiated.

ALAMEDA APPLIED SCIENCES CORP. 2235 Polvorosa Ave, Suite 230 San Leandro, CA 94577
Phone: PI: Topic#:	(510) 483-4156 Dr. Rahul R. Prasad AF 01-180 Awarded: 29APR01
Title:	High power, high voltage, ultra-fast, UV triggered diamond switch
Abstract:	Alameda Applied Sciences Corporation (AASC) proposes to develop a new type of high voltage, high power diamond switch potentially capable of switching GW power levels at ~100 kV. The basic element of this switch is a thin disk of natural or CVD diamond that supports up to 25 kV, is triggered into conduction by UV radiation, achieves rise/fall times <1 ns (limited mostly by the rise/fall times of the trigger) and conducts ~1 kA/cm2 at repetition rates ~10 MHz. This basic element may be combined in series to hold-off higher voltages and in parallel to carry higher currents. Our Phase I goal is to demonstrate a 25 kV/10 A unit module, followed by series/parallel combinations to achieve 100 kV/10 A or 25 kV/40 A switching. Such UV triggered switches could be the key enabling technology for a variety of pulsed power applications that have had to rely either on bulky and unreliable gas switches or stacks of semiconductor switches in series. Our Phase I project aims to establish well founded limits to the capabilities of the new diamond switch, in the context of competing technologies such as series stacks of Si IGBTs, light triggered GaAs switches and emerging SiC technologies.The research proposed here could lead to a family of new solid-state switches that will find widespread application in aerospace systems, military radar, power transmission in the grid, high speed rail traction, uninterruptible power supplies for semiconductor manufacturing and automobile manufacturing.

APPLIED PHYSICAL ELECTRONICS, L.C. 602 Explorer Austin, TX 78734
Phone: PI: Topic#:	(512) 264-1804 Dr. Jon R Mayes AF 01-180 Awarded: 22MAR01
Title:	Compact Pulsed Power Sources
Abstract:	Compact pulsed power systems and power sources are rapidly becoming important in aerial-based military systems. With the increase usage of High Power Microwaves (HPM), advanced radar systems, electrical propulsion systems and space based laser systems state-of-the-art pulsed power modules take on increasing importance. Applied Physical Electronics, L.C. proposes two systems that offer compact, high power sources designed to meet the needs for short pulse and long pulse delivery needs. Both systems are presented as driver supplies for high power microwave generation; however, their use extends beyond that scope. Two systems are proposed: First, an Ultra Wideband voltage impulse, designed to deliver several GW pulses with pulse widths of a few nanoseconds and at repetition rates of up to 100 Hz. Second, a long-pulse system that is designed to deliver a 50 ns envelope of high frequency microwave energy (35 - 70 GHz). Each system is based on APELC's specialized development of compact Marx generators for missile defense and covert radar systems. Expertise in power systems is offered by Texas Tech University, completing the system. Portable RF generators may also see equal opportunities in the commercial market as well. UWB sources may be used for impulse radar systems for drug interdiction. These same sources may also be beneficial during drug raids, disengaging the communications of the unfortunate. High powered microwave systems may also be used for food and water treatment.

INNOVATIVE SCIENTIFIC SOLUTIONS, INC. 2766 Indian Ripple Rd Dayton, OH 45440
Phone: PI: Topic#:	(937) 252-2706 Dr. Peter Bletzinger AF 01-180 Awarded: 10APR01
Title:	Pulsed Power Technology for Aerospace Applications
Abstract:	Many applications exist for high-power, high repetition rate, long-life switches in Air Force missions. While considerable progress has been made in the art of high-power switching over the past few years, the switch rise time, life time and rep rate for portable, small-scale pulse power systems still requires improvement for present and future Air Force applications. For generating high-peak-power (> GW) pulses at high rates, the use of spark gaps with liquid dielectrics as switch media is proposed rather than the commonly used gas switches. Because of the high dielectric strength of polar liquids (on the order of 1 MV/cm), liquid dielectric switches require relatively small electrode gaps. The small switch volume makes it possible to remove the liquid quickly after each shot. By integrating the switch into a flow system, a switch volume with typical dimensions of several hundred microns can be replaced in less than 1 ms (kHz rep rate) for a flow velocity of 1 m/s while retaining rise times of 1 ns or less. It is proposed in Phase I of this project to study the characteristics of water switches in static and flow modes and to use the results to determine the potential of these switches for kHz-rep rate operation. Phase II will be focused on the optimization of the switch at realistic power levels and rates. In addition, we will include the concept of polar liquids as dielectrics in the Pulse Forming Network as a means to reduce the size of the high-power pulse generator. Also addressed will be the problem of low-jitter triggering of liquid dielectric switches; applications in the generation of large-volume, high-pressure plasmas for "plasma stealth"; MHD power generation; and supersonic combustion. The feasibility of using these types of switches for greatly reducing the size of Marx banks will also be investigated.The primary benefits of this program will be the development of compact high-power, high-rep rate, long life switches for a variety of Air Force missions. Applications of these switches include: 1) generation of high-pressure, large volume plasmas for "plasma stealth", 2) MHD power generation, and 3) supersonic combustion.

MATERIALS & ELECTROCHEMICAL RESEARCH 7960 S. Kolb Rd. Tucson, AZ 85706
Phone: PI: Topic#:	(520) 574-1980 Dr. Sohrab Hossain AF 01-180 Awarded: 12APR01
Title:	Development of Lithium-Ion Cells for High Rate Pulse Power Applications
Abstract:	A novel approach for the development of a lithium-ion battery system is proposed for pulse power aerospace applications. The approach involves fabrication of thin-film electrodes with nano-particles cathode and anode materials having high capacity and high rate capability, use of high lithium-ion conductive electrolyte, fabrication of prismatic design pouch cells, and testing of the developed cells to demonstrate the proof-of concept. The thin film electrodes will be characterized using different analytical and electrochemical techniques.The rechargeable battery market is growing rapidly and lithium-ion batteries are taking over the market share from Ni-MH and Ni-Cd even with the higher cost. The successful completion of Phase I work will demonstrate the feasibility of developing a new high specific power rechargeable lithium-ion battery system. The rechargeable lithium-ion batteries developed with the proposed nanoparticles cathode and anode materials will provide superior specific power to the present state-of art rechargeable batteries and will have a broad commercial applications to the growing demand of high power portable electronic devices.

LUNA INNOVATIONS, INC. 2851 Commerce Street Blacksburg, VA 24060
Phone: PI: Topic#:	(540) 953-4290 Dr. Wade Pulliam AF 01-181 Awarded: 23MAR01
Title:	High-Temperature, Micromachined, Fiber Optic Sensor Suite for Gas Turbine Applications
Abstract:	Acquiring transient point measurements of temperature, pressure and acceleration in gas turbine environments is very difficult using currently available sensor technology. The current state-of-the-art often requires researchers to sacrifice frequency response for increased accuracy, forcing them to make assumptions about the transient nature of the environment being monitored. Clearly, there is a need for a suite of sensors capable of acquiring transient measurements in high-temperature gas turbine environments at discrete points. Luna Innovations proposes to develop a fiber optic temperature, pressure and accelerometer suite capable of acquiring transient point measurements in high-temperature, propulsive environments. The operating principle of the probe will be based on proven extrinsic Fabry-Perot interferometric (EFPI) techniques. Luna will use its extensive experience developing and commercializing fiber optic sensors technology to design, develop, and construct the proposed advanced temperature probe for combustion environments. The data obtained by these sensors will be invaluable for validation and development of CFD codes for combusting flows. This instrumentation is crucial to the development and operation of affordable and efficient 21st century gas turbine engines.Research in the high temperature instrumentation area will provide transducers with commercial uses that will include 1) aerospace, 2) high-temperature monitoring in power generation facilities, 3) high-temperature industrial process monitoring, and 4) automotive sensing for engine health monitoring and control.

APPLIED TECHNOLOGY ASSOC., INC. 411 NW 97th LANE CORAL SPRINGS, FL 33071
Phone: PI: Topic#:	(954) 346-9576 Dr. Robert Cavalleri AF 01-182 Awarded: 12JUN01
Title:	Energetic Solid Rocket Nozzle / Throat Insulator Concept
Abstract:	Throat erosion of rocket nozzles results in lower expansion ratios and reduced specific impulse. The erosion can be minimized or completely eliminated by employing throat cooling to keep the throat material below the throat material critical temperature. Evaluation and fabrication of a cooled non-eroding will be performed using Computational Fluid Dynamics (CFD) and simplified thermal analysis in conjunction with carbon fiber reinforced metal composite materials. This capability has been developed by Applied Technology and Metal Matrix Cast Composites in prior efforts on jet vane thrust vector control and electronic thermal management. The ability to fabricate cooled composite materials offers the possibility of eliminating throat erosion and maintaining rocket motor design values of specific impulse. Further refinement of this fabrication technology can increase the temperature limit of gas turbine components. The objective of the proposed effort is to use CFD and a transient lumped parameter analysis and pressure infiltration casting to evaluate, design and fabricate a high temperature cooled throat.The development of new materials coupled with cost effective CFD and thermal analysis greatly increases the ability to optimize the design of high temperature components. Applications are: internal spark ignition and diesel engines, gas turbine engines, solid and liquid rocket propulsion systems, etc. Increased temperature limits for all types of propulsion (rocket or jet engine) components has a positive impact on developing advanced propulsion systems and increasing the performance of these systems

PHYSICAL SCIENCES, INC. 20 New England Business Center Andover, MA 01810
Phone: PI: Topic#:	(979) 689-0003 Dr. John D. Lennhoff AF 01-183 Awarded: 10MAY01
Title:	Develop and Demonstrate Inflatable Reflector Technology
Abstract:	Physical Sciences Inc. (PSI) responds to the Air Forces need to demonstrate the viability of inflatable optics deployed from picosatellites. The PSI PicoSat Inflatable ((PSI)2) will be designed to provide surface metrology data during optic inflation pressure changes, and through eclipse. PSI will set design goals for optical performance and mission lifetime and apply them to the allocation of the available space on two tethered picosatellites. One picosat will contain an inflatable optic with torus and standoff truss, inflation and make-up gas, and imaging systems. The other picosat contains data logging, control and management, communications, and power. PSI has considerable experience successfully developing inflatable optics, and has designed and constructed experiments for the space environment for over a dozen missions. PSI has teamed with Prof. Robert Twiggs, of the Stanford University Space Systems Development Lab, to assist the data logging control and management, communications, and power design and optimization. On a Phase II effort, PSI will build the (PSI)2 dual tethered picosats, that will be launched and tested on a Phase III effort.Low cost SmallSats with sub-kilogram masses that utilize inflatable optics to view regions of the Earth have widespread commercial applications. Aerial viewing of any region of the planet could be achieved with low cost launch fees because of the light-weight of picosat imagers. Law enforcement, weather surveillance, regional high resolution mapping, and agriculture and fisheries monitoring could all be achieved through low cost, light weight imaging picosatellites.

SRS TECHNOLOGIES 500 Discovery Drive Huntsville, AL 35806
Phone: PI: Topic#:	(256) 971-7804 Mr. Paul A. Gierow AF 01-184 Awarded: 12JUN01
Title:	Advanced Photovoltaic Arrays for Solar Concentrators and Inflatable Antennas
Abstract:	Membrane concentrators have a low specific mass, high packaging efficiency and can be deployed in space to provide large amounts of collected energy. SRS has recently demonstrated all of the key elements of a concentrator for a near term space experiment. Addition of recently invented technologies of polyimide flexible PV cells to elements of the collector system offers to provide power to the spacecraft bus thereby using the collector aperture as power generation sources. The proposed effort will address key issues of flexible PV arrays. The traditional cover glass used to reject thermal loads will be replaced with a transparent polyimide with high emissive thermal property. The developed cell will then be applied to the support torus and of the membrane to provide power to the satellite bus. Innovations in doubly cast PV arrays will also be addressed to research the addition of the cells into the actual reflective membrane surface.Research is currently being done by a number of scientists within DoD and industry to increase the efficiency of flexible thin film PV cells from the 3-8% to the 10+% range. The development of increased efficiency flexible membrane cells could replace the traditionally accepted composite rigid panel mounted cells in the near future. In addition a number of potential commercial applications could benefit from the technology like the PV skins of long duration UAV's.

BUSEK CO., INC. 11 Tech Circle Natick, MA 01760
Phone: PI: Topic#:	(508) 655-5565 Mr. B. Pote AF 01-185 Awarded: 03MAY01
Title:	A Hall Thruster Array for Very High Power Propulsion Applications
Abstract:	Hall thrusters in the 50 - 100 kW class are an enabling technology for affordable methods of on-board propulsion for a number of orbit transfer and space tug applications. Studies of advanced propulsion options for deployment of payloads from a drop-off altitude to an operating orbit can be best achieved by high power Hall thrusters. These studies show a substantial payload mass increase per launch vehicle compared with all chemical propulsion systems. In the proposed Phase I program, Busek will demonstrate an array of thrusters operating as an integrated high power system. The viability and scalability of the proposed approach will be evaluated using a cluster of 600 W thrusters. The Phase I program is a subscale system demonstration for an array of 10 - 20 kW class engines envisioned as the building blocks for the 50 -100 kW system. Through a combination of direct experimental measurements, analysis and modeling activities, we will develop a definitive understanding and basis for a multi-thruster array as opposed to a single engine system. In Phase II we will continue with system development and testing and deliver to the Air Force a prototype high power cluster for testing in AFRL's propulsion and diagnostic test facilities.A high power Hall thruster propulsion system configured from standardized thruster modules will result in a lower cost, higher reliability propulsion system compared to a single high power engine. Configuring a customized high power system from lower power building blocks provides immediate dual use commercial applications because the standardized individual thruster has a viable market on commercial, military and government satellites. In addition, the multi-thruster array can be used to produce uniform high current, broad area ion beams and find terrestrial applications in etching and film deposition using reactive gas precursors.

ECOTECH 3239 MONIER CIRCLE, #4 RANCHO CORDOVA, CA 95742
Phone: PI: Topic#:	(916) 631-6310 Mr. Charles E. Grix AF 01-186 Selected for Award
Title:	Micropropulsion Thruster for Low Power Satellites
Abstract:	This study will identify and verify a higher performance and density electrically controlled solid propellant. The propellant under investigation utilizes the energetic oxidizer Hydroxylamine nitrate with other nitrate co-oxidizers that prevent oxidizer crystallization down to 20 degrees centigrade and lower. The oxidizers are combined with the energetic polymer polyvinyl amine nitrate (PVAN) and are processed as a solution solid propellant. While this system is highly conductive, it liquefies at temperatures above 100 degrees centigrade and does not readily extinguish once ignited. This makes it infeasible for use as an electrically controlled extinguishable solid propellant as is. To overcome these drawbacks requires chemically crosslinking the polymer after the propellant has been mixed, cast and solidified through the plastisol cure. This will ensure propellant dimensional stability during combustion. Liquid, electrically conductive additives will also be incorporated into the propellant that will aid in extinguishment when voltage is turned off. This will be verified in small test sample burns using both ac and dc electric current. The voltage, current and thrust will be measured and utilized to identify power requirements associated with propellant ignition, burn rate and extinguishment.The proposed propellant system would provide a more energetic and reliable propulsion system for the precise placement of low power microsatellites. In addition, this is a low-hazard, low-toxicity system that could replace current toxic and problematic liquid and solid propellants utilized in ship based munition systems.

ADVANCED CERAMICS RESEARCH, INC. 3292 E. Hemisphere Loop Tucson, AZ 85706
Phone: PI: Topic#:	(520) 434-6392 Dr. Ranji Vaidyanathan AF 01-187 Awarded: 10MAY01
Title:	Low Cost Ceramic-Lined Rocket Motor Case Design
Abstract:	In this phase I SBIR program, a team led by Advanced Ceramics Research, Inc. (ACR), and its partners propose the development of an innovative integral co-cured rocket motor casing comprised of a graphite/epoxy shell with a novel heat shield and liner fabricated from ACR's patented gelcasting ceramic material. The novel combination of materials will provide a unique synergy where the graphite/epoxy will provide structural rigidity, while the cured ceramic material will provide an ablative skin and moisture protection to the structural graphite/epoxy layer, enabling long-term storage of the casing materials. The graphite-epoxy shell, the ceramic liner and ceramic shell reinforced with carbon fibers will be fabricated using a patented process. In the phase I program, the ACR led team will prove the concept and fabricate composite coupons. Additionally, ACR will develop guidelines and procedures for optimizing the performance of composite motor casings and provide a parametric analysis and preliminary cost/economic analysis for prototype rocket motor casings. In the phase II program, the ACR led team will scale up the manufacturing process for fabricating full-scale components.The material developed in this Phase I program will be evaluated for number of high temperature applications. The ability to fabricate such components from a combination of polymer composites and ceramic composites would be advantageous to a number of customers who are contemplating the use of high temperature composite systems but cannot afford the cost of an all-ceramic component.

CORNERSTONE RESEARCH GROUP, INC. 2744 Indian Ripple Rd. Dayton, OH 45440
Phone: PI: Topic#:	(937) 320-1877 Mr. D. Ernest Havens AF 01-187 Awarded: 23MAY01
Title:	Novel Rotomolding of Advanced Composites for Rocket Motor Cases
Abstract:	The future of enhanced tactical missile systems hinges on the development of significant innovative improvements in the manufacture of solid rocket motor casings. Leading engineers in the solid rocket motor industry believe further development with metal cases will not prove adequate. Current manufacturing of composite motors is labor intensive and the end product is simply inadequate overall. The consensus is that the future needs may be satisfied by the use of continuous fiber reinforced three-dimensional (3-D) microstructural composites made with advanced resin systems and materials. In order to mass-produce a more ideal rocket motor a new process must be developed that will turn out highly structured composite parts consistently and in a manner that minimizes skilled labor input. We propose to incorporate the use of advanced materials into our existing composite rotomold tank process and further the development of the rotomold process to manufacture multi-layer composite microstructured solid rocket motor cases to be used for future tactical missile development. The extension of this technology to the manufacturing of solid rocket motors will bring significant unit cost reductions. This proposal discusses Rotomold composite development and advanced composite materials processing for the low-cost manufacturing of composite solid rocket motors. The development of this technology will provide the means for actualizing current enhanced tactical missile system concepts. One of the primary limiting factors of these enhanced systems has been propulsion. By overcoming this limitation a new aerospace market of advanced missile system development and high performance propulsion will be established.

TECHNANOGY SPACE 1601 N. Alton Irvine, CA 92606
Phone: PI: Topic#:	(949) 261-1420 Mr. George Whittinghill AF 01-188 Selected for Award
Title:	Develop and Demonstrate a Hybrid Powered Missile Motor
Abstract:	Technanogy Space proposes to study, design, manufacture and test several hybrid rocket motor grains at the 100 to 300 lb thrust level, loaded with 40 nano-meter sized constituents with the express objective to push hybrid fuel regression rate by at least an order of magnitude over the current state of the art. Technanogy Space further intends to couple the data obtained from these motor tests with a missile system model to build a trajectory simulation environment to optimize the propellant choices and burn duty cycle. A short duration, high thrust motor firing will be made to verify the scalability of the results. Such an advance would make nano-propellant enhanced hybrid rocket motors suitable for tactical use and would exceed the performance possible from solid rocket motors in the same application.A successful demonstration of high performance nano-enhanced hybrid rocket motors has sweeping ramifications for the propulsion industry. As hybrid propulsion is recognized to have the lowest installed cost per pound of thrust of any propulsion system, this new technology may be cost effectively introduced into tactical missiles, sounding rockets, booster stages, upper stages and on-orbit maneuvering vehicles for even greater performance gains.

TIES, INC. 8410 Jennie Avenue NE Bainbridge Island, WA 98110
Phone: PI: Topic#:	(206) 909-0943 Mr. Ron Thue AF 01-189 Selected for Award
Title:	Develop Mechanical Aging Criterion for Energetic Materials
Abstract:	The standard failure criterion for solid rocket propellant requires the evaluation of current loads (stress or strain) and a comparison of those loads to the material capability for the given loading conditions (time and temperature). However, propellant often fails at lower load levels than predicted using this method. This is a consequence of the failure to consider cumulative damage effects resulting from sometimes-extreme loading histories. A comprehensive method of evaluating cumulative damage for propellant needs to be developed. This is especially true for tactical motors that undergo extreme loading histories through their lifetime. In this proposal we approach cumulative damage model development in three stages: First, a review of existing cumulative damage models paying particular attention to the TTCP KTA 4-29 findings; Second the evaluation of existing cumulative damage models for their strengths, weaknesses and predictive capabilities; Third, the extension of existing model capability to include temperature effects, biaxial and triaxial effects, and high-strain modulus/Poisson's Ratio effects as is reasonable within the Phase 1 SBIR scope. Consideration will also be given to other model needs identified via the TTCP KTA 4-29 work. The Phase I research will include a literature review of existing theories of propellant aging and cumulative damage in conjunction with the TTCP KTA 4-29 project. Using the vast history of propellant failure testing available at Thiokol, the different available theories will be evaluated. Where shortcomings exist with the theories, a new theory (or modifications to exiting theories) will be proposed which better matches test results. At the end of this study, a theory for failure of aging solid propellant will be formulated, derived from the best available published work, extensions to that work, and backed by existing test data.

CERAMIC COMPOSITES, INC. 1110 Benfield Blvd. Millersville, MD 21108
Phone: PI: Topic#:	(410) 224-3710 Dr. Mark Patterson AF 01-190 Selected for Award
Title:	Very Light-Weight Divert Propulsion Systems
Abstract:	The next generation of rocket propulsion thrusters will be required to be lighter, and provide higher thrusts with no increase in the cost of manufacturing. The fabrication of a very light weight propulsion systems is proposed through the integration of a light weight ceramic injector with a ceramic matrix composite nozzle. This approach will reduce the mass of the system by over 50%. The injector will be fabricated by low cost stereolithography and intimately attached to the nozzle during densification via a rapid, low-cost CVI technique. The performance of the light weight system will be demonstrated with H2 and O2 propellants. The proposed fabrication approach will reduce the mass of the propulsion system by 50% leading to a greater Isp, faster response times and range, and a lower access to space cost. In the future, reduced thermal transfer through the injector will lead to the ability to use PMC fuel lines further reducing the overall propulsion system weight. CCI will work closely with Primex Aerospace Corporation to design and develop a commercial unit for future propulsion systems.

CONTAINERLESS RESEARCH, INC. 906 University Place Evanston, IL 60201
Phone: PI: Topic#:	(847) 467-2678 Dr. Paul C. Nordine AF 01-190 Awarded: 24MAY01
Title:	Advanced Rocket Propulsion Technologies
Abstract:	This Phase I SBIR research proposal will investigate the feasibility of a continuous high flux source of boron vapor for preparing B/para H2 cryosolids for HEDM research. The boron source apparatus will be designed for the preparation of 5 mol% B/pH2 solids at rates sufficient to form transparent material and for integration with the cryo-solid spectroscopy apparatus at AFRL. The proposed approach involves free evaporation of pure boron atoms from a thin layer of liquid boron in a high vacuum environment. The liquid boron, formed by CO2 laser beam heating and superheated at its surface, will coexist with an underlying layer of solid boron that supports the liquid. Research objectives are to (i) demonstrate the purification of boron using containerless processing of liquid boron, for use in the vapor source, (ii) fabricate a test chamber for vaporization experiments, (iii) perform experiments to determine the operating conditions to obtain a stable, continuous, known and well-controlled intense boron vapor flux, and (iv) develop the design for the apparatus to be developed in Phase II. In Phase II, we would develop and deliver the high flux boron vapor source to AFRL for use in the Air Force's HEDM research program.The R&D will benefit the Air Force HEDM research program by satisfying a key issue of the Cryogenic HEDM Solid Prospectus. It will open markets for CRI in advanced systems to conduct research on cryo-solid HEDM. It will provide the means to supply, for the first time, ultra-pure elemental boron, as a solid element and as a vapor for vapor deposition applications, in Dual-Use R&D markets.

PYRODYNE, INC. 11280 Panorama Drive New Market, MD 21774
Phone: PI: Topic#:	(301) 607-6108 Dr. Frederick S. Billig AF 01-190 Awarded: 10MAY01
Title:	Technology for Affordable RBCC Vehicle Development
Abstract:	This SBIR initiates a technology program to develop affordable cryogenic and storable fueled Rocket Based Combined Cycle RBCC vehicles for space access missions. The cryogenic fueled RBCC is the 2nd stage of a Two-Stage-To-Orbit TSTO vehicle that has been boosted by a JP fueled turbine based 1st stage to 3,500-4,500 ft/s. The storable-fueled RBCC is a 1st stage that boosts a cryogenic fueled rocket 2nd stage to 8,000ft/s. Conceptual designs of three candidate space access vehicles serve as the basis for defining the engine flow paths, sizing the ejector-injector motors, identifying the key technical challenges, defining the test cell apparatus, and planning for vehicle development. A key element for affordability is the development of low cost ejector-injector motors. A significant portion of the Phase I effort will be directed to this task. The test apparatus will be sized for testing in the USAF Edwards, CA Test cells 2a and in a research facility. The ejector-injector motors will be fabricated and tested in Phase II.The principal tangible products of this SBIR will be the design of three RBCC powered vehicles for space access missions and the associated ejector-injector motors. Low cost cryogenic and storable fueled ejector-injectors will be developed for general use in RBCC engines. Both military and commercial customers are anticipated for these space access vehicles and these key engine components. Two major aerospace companies have reviewed and strongly endorsed this SBIR Proposal. Both companies will closely follow the progress of the Phase I effort for consideration of becoming Fast Track sponsors of a Phase II effort. Marketing of the vehicle concepts and ejector-injector motors will be initiated during the Phase II Program and the capitalization effort of PYRODYNE for Phase III and beyond will be initiated.

ROTORDYNAMICS-SEAL RESEARCH 3628 Madison Ave #20 North Highlands, CA 95660
Phone: PI: Topic#:	(916) 344-9500 Dr. Joseph K. Scharrer AF 01-190 Awarded: 10MAY01
Title:	Transient Turbopump Simulation
Abstract:	Cryogenic turbopumps utilizing fluid film bearings have unique nonlinear transient characteristics. The effort proposed herein will apply proven theoretical models to the simulation of the transient operation of a cryogenic turbopump supported on fluid film bearings. The final analysis tool will enable the designer to predict the transient characteristics of the turbopump for any desired profile representing different environments such as a test stand or engine installation.Low cost development of turbomachinery utilizing fluid film bearings.

CERACON, INC. PMB 330, 5150 Fairoaks Blvd. # 101 Fairoaks, CA 95608
Phone: PI: Topic#:	(916) 783-4899 Mr. Henry S. Meeks AF 01-191 Awarded: 10MAY01
Title:	Quasi-isostatic, Solid-State Forging of a Nanophase Aluminum Alloy for Rocket Turbopump Components
Abstract:	Research to establish the potential performance benefits of nanocrystalline engineered materials (grain size less than 100 nanometers) gained momentum in the mid-1990��s (1). Significant effort has since been focused on the areas of powder preparation, powder consolidation, microstructure evolution and control, and product fabrication technologies. Powder consolidation has been achieved primarily by hot isostatic pressing (HIP) which is governed by diffusion mechanics and requires exposure of the nano-powders to a temperature of (315,a C) for extended periods of time (3 hours). The process is expensive and can easily result in a loss of nanocrystallinity due to rapid and unpredictable grain growth. Low (15 ksi/104 MPa) isostatic pressures are unable to break-up tenacious powder surface oxides thus requiring extensive secondary deformation processing to obtain usable material. The Ceracon,� Powder Forging Technology uses a conventional hydraulic forging press, and is a cost effective, near-net-shape alternative to HIP. High uniaxial ram pressure (127 ksi/876 MPa) is transformed into a quasi-isostatic pressure field through the use of a granular �.pressure transmitting media�" or PTM. The resultant shear stress is directly responsible for mechanical break-up and re-distribution of deleterious powder particle oxides. Consolidation of the nano-powder to full density occurs within seconds via plastic yielding which is virtually instantaneous, thus preserving the nanophase structure. reduced manufacturing costs; shorter delivery lead times; isotropic physical and mechanical properties; reduction/elimination of extrusion steps; automotive connecting rods, rocket engine turbopump components, cryogenic sealing flanges

UES, INC. 4401 Dayton-Xenia Road Dayton, OH 45432
Phone: PI: Topic#:	(937) 255-1320 Dr. Oleg N. Senkov AF 01-191 Awarded: 10MAY01
Title:	Advanced Aluminum Materials for Rocket Turbopump Rotors
Abstract:	The objective of the proposed program is to identify and develop aluminum based material that can replace the currently used Ti-5Al-2.5Sn ELI alloy as a liquid hydrogen pump impeller operating at 20�K. This application requires very high specific strength as well as adequate toughness and resistance to hydrogen embrittlement. Aluminum alloys are of particular interest because in comparison with titanium, their density is much lower, they are less expensive, can be processed and machined much easier, and they have very low susceptibility to hydrogen embrittlement. However, the currently available aluminum alloys cannot compete with titanium alloys because of low specific strength. During Phase I the mechanical properties of a conventional aluminum alloy (7XXX series) will be considerably improved through microalloying with Sc and Zr followed by special thermomechanical processing. The strength of the modified alloy will be increased to values equal to or exceeding 950 MPa at 20�K, with elongation of about 7%. The fact that a commercial Al alloy is selected will cut down significantly on development cycle costs. Development of this ultra-high strength aluminum alloy will help designers to improve engine performance by decreasing weight of rotor components, increasing impeller tip speed, and reducing complexity and cost.Development of super-high-strength Al-based material with good fatigue resistance will offer designers a real potential to improve the turbopump performance by decreasing the weight of rotor components, increasing impeller tip speed, and significantly reducing complexity and cost. Current titanium impellers such as those used on the Space Shuttle Main Engine (SSME) require complex, high-maintenance, polymeric seals because of concerns about metal-to-metal contact and titanium hydriding. The super-high-strength aluminum will eliminate this concern, simplifying seal design and improving seal life and reliability. This alloy will also find widespread use in the commercial aerospace and transportation sectors. Because higher specific strengths translate directly into reduced component mass without redesign, super-high-strength Al-based alloys will be attractive in any application where component mass and/or volume are constrained, e.g. orbital applications including, but not limited to: bus structures, truss nodes, brackets, hinges, radiator panels and PCB heat sinks. The alloy will also have a significant impact in sustainment, since direct component-for-component replacement will give higher performance in existing systems, e.g. extended component life and reduced maintenance for F-16 aircraft ventral fins. Additional impact will also be felt in the area of unitized design and construction, insofar as increased performance can be met at reduced cost through reducing numbers of parts and fasteners.

SOHAR, INC. 8421 Wilshire Boulevard, Suite 201 Beverly Hills, CA 90211
Phone: PI: Topic#:	(323) 653-4717 Dr. Herbert Hecht AF 01-192 Awarded: 25MAY01
Title:	Rapid Cost Estimates of Military Aerospace Vehicles (MAV's)
Abstract:	Despite the importance of life cycle costing (LCC), it has rarely been integrated into the design activity. One of the reasons has been the lack of easily learned tools that are cost effective and whose results are non-trivial, i.e., would be sufficiently powerful that development engineers would consider using them. In this research, we will develop a tool, which we call the Propulsion Life Cycle Cost (PLCC) Tool to address this need. PLCC will be capable of estimating the development, acquisition, operations, and maintenance cost of propulsion systems in particular and of the a complete Military Aerospace Vehicle (MAV) more generally. PLCC will be based on an enhancement of a successful off-the-shelf decision support tool for lifecycle costing called D-LCC. D-LCC will be enhanced with risk assessment, parts database, and other capabilities to tailor it for MAV applications. A key element in the success of this effort will be the seniority and expertise of the staff involved in cost data compilation, who will be effective in gathering cost data through their own experience and network of contacts. Because of the maturity of the baseline general purpose product being used in this effort, a fully functional software tool, together with documentation will be delivered at the end of the Phase I effortThe technology developed under this research will be useful in any organization with a Design To Cost (DTC) objective or operational environment in which capital and operating & maintenance budgets must be traded off. The PLCC tool will be marketed to the growing number of commercial and Governmental space entities. PLCC will be less expensive and easier to use than other currently available LCC tools. With the additional of application specific data, we anticipate having a competitive edge with which to enter the market.: PLCC, with its easily learned interface and its powerful, domain specific database will be a good match for this community of users.

BLUE ROAD RESEARCH 2555 NE 205th Avenue Fairview, OR 97024
Phone: PI: Topic#:	(503) 667-7772 Mr. Eric Udd AF 01-193 Awarded: 10MAY01
Title:	Fiber Grating Sensor System to Determine Motor Case Damage
Abstract:	This Phase I SBIR will develop a fiber grating sensor system that is capable of locating and assessing damage on a composite rocket motor casing. Blue Road Research will use arrays of single and multi-axis fiber grating strain sensors to perform both localization and detailed assessment of the damage using a series of fiber grating demodulation methods that allow multiplexing of large number of sensors as well as multidimensional strain field analysis. Specific areas that will be investigated will include delamination and breakage of fibers in the composite casing.This technology could be used to support damage assessment and health monitoring on a wide variety of aerospace platforms both military and commercial that employ composite materials. These structures could include wings and flight critical components on aircraft. It is also possible that this technology could be utilized on ships, bridges and other large structures where composite materials are playing an ever more important role.

ALPHA OMEGA ELECTROMAGNETICS, LLC 24 Cascade Road Arnold, MD 21012
Phone: PI: Topic#:	(410) 750-0190 Dr. Eric W. Lucas AF 01-200 Selected for Award
Title:	Ultra Wide Band RF Antenna Element
Abstract:	The objective of this SBIR effort is to develop and demonstrate the technical feasibility of an improved ultra wideband antenna element technology suitable for both receive and transmit functions. The end goal is to significantly extend the current state-of-the-art in ultra wideband phased array and individual antenna technology, both from a performance as well as from a practical implementation standpoint. Efforts under this SBIR will focus on the development of several novel antenna architectures that are derived from the fundamental ultra-wideband electromagnetic mechanisms associated with so-called notch (Vivaldi) radiator. The proposed research program is strategically partitioned to address developments in both the ultra-wideband scanning phased array technologies as well as the ultra-wideband individual and low-to-medium gain antenna technologies. AOE proposes to investigate several novel antenna architectures from both categories, as both areas of technology clearly find important applications. In this heavily electromagnetic-simulation-based investigation, AOE will pursue technological advances not only with respect to ultra-wideband radiation performance, but also with respect to important practical antenna implementation issues, such as aperture cost, weight and physical profile (depth). AOE will use its own proprietary, 3D hybrid finite-element / method-of-moments phased array electromagnetic simulation software in addition to commercially available EM simulation tools to conduct this investigation.The results of this research will have far-reaching commercial and military applications with respect to ultra wideband communication, radar and multifunction systems. The resulting wideband antenna technologies can be used to reduce the required number of antenna apertures on military aircraft, ships and other vehicles that are already overpopulated with antennas. Additionally these technologies can be applied to commercial `smart antenna' applications and wall and ceiling mount PCS antenna applications.

MISSION RESEARCH CORP. Post Office Drawer 719, 735 State Street Santa Barbara, CA 93102
Phone: PI: Topic#:	(937) 429-9261 Dr. William J. Kent AF 01-200 Selected for Award
Title:	Ultra Wide Band RF Antenna Element
Abstract:	This proposal will investigate innovative wide bandwidth and multi-band antenna elements for both receive and transmit functions. Antenna elements to be investigated but not limited to, are: sprial, log-periodic, end-loaded dipoles, vertical monopoles, and sinuous spiral antennas. The antenna elements will have the following features: 1) fixed polarization across the bands of interest; 2) target bandwidth (though not limited to): HF through GHz; 3) multifunction capability to minimize the total number of aircraft apertures; 4) compatibility with RF/photonic wide band links. The objectives of this proposed Phase I effort are to study candidate apertures using MRC/MSU developed conformal antenna modeling codes, selecting one or more apertures for further development and prototyping in Phase II, integrating project output with current and projected Air Force aperture requirements, and identifying multifunction apertures that can be transitioned for civilian use (especially for existing and emerging wireless data, voice, and geolocation devices). In Phase II, the apertures will be further simulated and prototype apertures will be designed, built, and tested.1 - Multifunction apertures provide new functionality while reducing aircraft skin penetrations. 2 - Ultra wide band apertures permit higher data rate transmission and more thorough electronic warfare coverage. 3 - Multifunction antennas can be designed to reduce the aircraft's signature.

PACIFIC WAVE INDUSTRIES, INC. 10390 Santa Monica Blvd.,, Suite 100 Los Angeles, CA 90025
Phone: PI: Topic#:	(310) 229-0099 Dr. Boris Tsap AF 01-201 Awarded: 01JUL01
Title:	60 GHz Polymer Modulators for Millimeter Wave Analog Photonic Links
Abstract:	Pacific Wave Industries proposes the design of a 60 GHz push-pull Mach-Zehnder polymer modulator exhibiting a DC Vp of 5 volts. The proposed device will be fabricated from our PC/CLD material system, which exhibits several advantageous device properties. This proposed structure incorporates Ag electrodes for the novel RF modulator drive circuit, the higher conductivity of Ag allows a 60 GHz bandwidth (3 dB point) with reasonable RF driving voltages. The full potential bandwidth of the device will be exploited by the design and implementation of millimeter wave coplanar waveguide to microstrip line transitions. The proposed device will significantly impact high performance millimeter wave optical links which have stringent demands on modulator performance. Preliminary investigations of the impact of the proposed device on link performance are found in this proposal, with the details outlined as part of the tasks. This Phase I project will produce polymer amplitude modulators with electrical bandwidths of 60 GHz. These cost effective devices, with relatively low half-wave voltage (Vp) and ultra high bandwidth will have an immediate impact on the development of high performance RF links. The ability to reduce the cost of analog optical millimeter wave links and to improve their performance will allow its implementation for huge potential markets.

ALPHATECH, INC. 50 Mall Road Burlington, MA 01803
Phone: PI: Topic#:	(703) 284-8444 Dr. William H. Bennett AF 01-202 Awarded: 11APR01
Title:	Fusion of GMTI Reports from Multiple Sensors in Clutter
Abstract:	Airborne systems for ground surveillance of mobile targets are increasingly providing significant tactical information for military operations. Fusion of ground moving target indicator (GMTI) radar data from multiple airborne platforms with overlapping fields of regard can improve tracking of moving ground targets. OSD is actively working to establish capabilities collaborative surveillance tasking and exploitation of airborne surveillance data. In many operational scenarios GMTI performance is limited due to excessive ground clutter, target motion and airborne platform surveillance geometry. Modern methods in multiple target tracking can be enhanced to provide improved fusion of GMTI radar data by exploiting known properties of airborne GMTI radars. Improved sensor models which can predict detection and measurement precision for specific classes of radars in various clutter levels are needed to enable improved tracking. This effort will produce software tools to enable enhanced fusion of GMTI radar data from multiple platforms.Airborne surveillance radar is rapidly finding commercial applications in traffic monitoring, land use survey, and transportation system monitoring. As GMTI radar becomes available for commercial exploitation tools will be in demand. Track fusion processing is a rapidly maturing military technology that holds potential for commercial applications in perimeter and site internal security, airport ground collision avoidance, transportation monitoring and survey and other applications. Improved tracking algorithms will enable the development of robust software tools that produce reliable information products from radar surveillance data in formats that can be directly interpreted by a wide range of users.

ALPHATECH, INC. 50 Mall Road Burlington, MA 01803
Phone: PI: Topic#:	(703) 284-8411 Dr. Andrew J. Newman AF 01-203 Selected for Award
Title:	Dynamic Multi-Asset Management
Abstract:	ALPHATECH proposes to develop techniques and tools for near real-time dynamic re-tasking of ISR sensors under realistic operating conditions. Effective ISR resource management must coordinate a diverse set of assets with a wide range of capabilities operating in an uncertain environment satisfying a rapidly evolving set of information needs. This involves ISR resource management over a range of planning levels and time scales. These include mode scheduling for individual sensors at time scales on the order of a beam dwell, as well as platform route planning and sensor-to-task assignment at times scales on the order of the mission time horizon. Recent research efforts conducted by ALPHATECH have demonstrated efficient algorithms for the resource management problem at both of these levels. However, these efforts did not consider the problem of coordinating multiple planning levels and time scales. In this proposed effort, we will leverage these technologies, and address the coordination problem by developing novel algorithms that overcome the explosive combinatorics introduced by the hierarchy of re-tasking problems. We will then implement an integrated, prototype, dynamic resource manager, and apply the tool to a selected example scenario of limited complexity and of particular relevance to Air Force information gathering.Many commercial processes could benefit substantially from dynamic resource management. Examples include power and communication network control, air traffic control, just-in-time manufacturing processes, supply chain distribution, transportation, and logistics planning. These processes all share the need for rapid decision making under uncertain and dynamically evolving conditions. The technologies developed under this SBIR would be broadly applicable to all of these, as well as many other, commercial applications.

DATA FUSION CORP. 10190 Bannock Street, Suite 246 Northglenn, CO 80260
Phone: PI: Topic#:	(720) 872-2145 Dr. W. Kober AF 01-203 Awarded: 09MAY01
Title:	Dynamic Operational Re-Tasking of ISR Sensors
Abstract:	Data Fusion Corporation (DFC), OptTek Corporation, and the Institute of Medical Cybernetics, Inc. (IMC) propose the development of algorithms and software for re-tasking distributed, multi-platform air-to-ground ISR sensing assets, as well as potentially re-routing these platforms. The approach will be based on the use of Tabu Search (TS) for near real-time combinatorial optimization. A Virtual Associative Network (VAN) for offline reinforcement learning of preferable alternative choices will support the TS process.Phase-III has many dual use possibilities, including multi and single robotic applications with distributed sensors, management of power and communication networks, intelligent vehicle control systems such as air-traffic control and intelligent-vehicle highway systems, and manufacturing operations.

FRONTIER TECHNOLOGY, INC. 6785 Hollister Avenue Goleta, CA 93117
Phone: PI: Topic#:	(703) 671-0508 Mr. G. Edward Crowder AF 01-203 Awarded: 13APR01
Title:	Dynamic Operational Re-Tasking of ISR Sensors
Abstract:	Improved command and control of ISR assets, to include scheduling and re-tasking those assets in a multi-objective operational environment with multiple resource, spatial, temporal, and operational constraints, will be necessary to realize fully the benefits of future ISR capabilities envisioned by Joint Vision 2020. The ISR asset scheduling and re-tasking problem is extremely complex and falls into a notoriously difficult to solve class of mathematical problems. Typically, solutions to this class of problems are either non-optimal or not attainable in reasonable time, or both. This project will develop and thoroughly test an adaptive hybrid intelligent system for real-time optimal scheduling and re-tasking of ISR assets in a realistic operational scenario involving a diverse set of ISR assets fitted with various sensors. The Phase I effort will prove the concept of this hybrid system and culminate in an end-of-phase proof of concept demonstration. Phase II will develop an operating prototype system. An adaptive hybrid intelligent scheduling and re-scheduling technology will be attractive to any organization that has to deal with large complex scheduling problems, such as supply chain and manufacturing firms, and transportation/shipping firms.

PRACTICAL IMAGINEERING, INC. 3055 Prosperity Avenue Fairfax, VA 22031
Phone: PI: Topic#:	(703) 573-9600 Dr. Daniel F. Lyons III AF 01-204 Awarded: 23APR01
Title:	Standard Image Compression for Data Link Transmission
Abstract:	The radar imaging community has expanded well beyond the traditional US military customer base. The success of various DoD and NASA projects in mapping the earth and measuring various terrain features has increased overall interest in SAR imagery. Indeed, measurements such as ocean temperature and water flows, as well as polar ice thickness measurements are essentially civilian applications of MASINT. Our approach compresses the complex data that has already been subject to image formation. This processing could occur on airborne SAR platforms, or at space borne SAR ground stations. In either case vast amounts of complex imagery need to be compressed either for dissemination or for archiving. If successful, the techniques developed in Phase I and implemented more fully in Phase II could be use to distribute compressed imagery to both civilian researchers and military users of SAR imagery. Reductions in storage and/or bandwidth for distributing SAR data could be expected on the order of 10 to 50 compared to lossless compression algorithms.This technology could be successfully 'commercialized' if an off-the-shelf compression software suite were made available to entities distributing and/or using SAR imagery. The use of SAR systems and data is increasing steadily within both the civilian USG and the Department of Defense. Indeed MASINT techniques are also finding dual-use in applications such as detecting illegal hazardous waste dumps, tracking forest fires, and monitoring air/water purity. The technology benefit is extremely leveraged since there is a limited number of SAR sensor systems (users of compression), but thousands of consumers of the product (users of decompression). The decompression stage could be made invisible to the user by embedding the decompression software into standard image analysis tools. The ideal commercial application would be to standardize the compression algorithms as part of the National Image Transmission Format (NITF), which would encourage widespread insertion of the technology into other commercial products.

SCIENTIFIC RESEARCH CORP. 2300 Windy Ridge Parkway, Suite 400 South Atlanta, GA 30339
Phone: PI: Topic#:	(770) 989-9486 Mr. Erik Kjeldsen AF 01-204 Awarded: 18APR01
Title:	Standard Image Compression for Data Link Transmission
Abstract:	Synthetic Aperture Radar (SAR) is a high-resolution, wide-area, active imaging technique usable in day-night, all-weather conditions. SAR-equipped airborne platforms, including the U-2 fleet, the Joint Surveillance Target Attack Radar System (JSTARS) E-8 and unmanned aerial vehicles (UAVs), and spaceborne platforms (satellites and the Shuttle), are rapidly proliferating the volume of data that must be piped over constrained bandwidth wireless links. The problem is exacerbated by an increasing commercial demand for these scarce spectrum resources and the DoD's desire to maximize the intelligence benefit of the SAR imagery. Tactical needs impose strict time constraints on imagery transmission delays. The push is on to preserve the image phase component allowing processing such as Interferometric SAR and facilitating Measurement and Signal Intelligence (MASINT) exploitation. A solution is to reduce the transmitted data volume using compression techniques. Popular standards-based compression for electro-optical imagery is ill-suited for the high dynamic range, speckled, and complex-valued SAR imagery. SRC therefore proposes to develop an innovative compression technique based on the wavelet packet transform that will dynamically adapt to the SAR data source statistical distribution. Our emphasis will be on researching suitable cost metrics and search algorithms yielding compression results that support automated exploitation and human interpretability.Compression of SAR image data using lossy Block Adaptive Quantization (BAQ) or lossless techniques does not provide the degree of reduction needed to transmit over commonly available wireless link bandwidths (e.g., T-1 = 1.544 Megabits per second). Our compression technology will overcome this wireless bottleneck with suitable compression ratios, providing benefit to a variety of SAR applications including oil spill monitoring, sea ice monitoring, agricultural classification and assessment, natural resource location, oceanography, topographical mapping, search and rescue operations, treaty verification, and non-proliferation monitoring.

VEXCEL CORP. 4909 Nautilus Court Boulder, CO 80301
Phone: PI: Topic#:	(303) 444-0094 Mr. Richard E. Carande AF 01-204 Awarded: 23APR01
Title:	Standard Image Compression for Data Link Transmission
Abstract:	Vexcel Corporation proposes to develop a general-purpose compression algorithm for use with complex SAR data. This algorithm will be general in nature and will not be tuned for any particular end-user application. Compressed data will retain the appropriate information required to perform coherent processing, ATD/R, ACD as well as other exploitation techniques including MASINT techniques. The algorithm will also be able to effectively compress data that is multi-channel. The compression algorithm is data dependent, and is expected to produce compression gains between 2 and 10. Vexcel proposes to perform limited demonstrations that may include independent quantitative exploitation evaluations.Compression of SAR data will allow more coverage and/or resolution to be obtained using existing radar technology, with no sacrifice in performance. This applies to civilian, commercial and DoD applications. Potentially, a general purpose compression scheme such as this may be useful over a broad range of future SAR system.

ALPHATECH, INC. 50 Mall Road Burlington, MA 01803
Phone: PI: Topic#:	(781) 273-3388 Dr. Mahendra Mallick AF 01-206 Awarded: 07MAY01
Title:	Multi-platform Multi-target GMTI Tracking with Out-of-sequence Measurements
Abstract:	Sensor platforms transmit data to a central tracker using communication networks in a multi-platform network-centric tracking system. Measurements can arrive out-of-sequence (OOS) at the central tracker due to varying data preprocessing times at the platforms, delays in transmission initiation, and communication network execution. The central tracker can also receive data out-of-sequence from a single sensor, if the sensor operates in multiple modes such as wide area surveillance and sector search modes. Previous researchers have addressed the OOS measurement (OOSM) filtering problem for a single target with one kinematic model, when the OOSM lies between the last two measurements (one-lag problem). We have developed and tested a new algorithm for the OOSM filtering problem, which handles multiple-lags using a single kinematic model. We propose to develop additional algorithms to handle multiple lags and multiple kinematic models. Previous efforts have used data reprocessing and buffering for multi-target multi-sensor tracking problems. These approaches are undesirable due to the high storage and CPU requirements. No algorithm exists at present that addresses the multi-target multi-sensor OOSM problem. We propose to develop new algorithms for data association and likelihood computations for OOSM multi-target multi-sensor tracking using our multiple-lag and multiple-model OOSM filtering algorithms.This research will benefit surveillance of the battlespace where out-of-sequence measurements can occur due to the use of multiple platforms to obtain a coherent and integrated picture of the battlespace. This effort will directly benefit a number of government funded programs such as MPTE, AMSTE, CAESAR, and DDB where real data collection and research include out-of-sequence GMTI sensor measurements. Commercial applications of the research include air traffic surveillance, border surveillance by the Drug Enforcement Agency and the Immigration and Naturalization Service.

MRLETS TECHNOLOGIES, INC. 616 Brookmeade Ct. Beavercreek, OH 45434
Phone: PI: Topic#:	(937) 657-2620 Dr. Shan Cong AF 01-206 Awarded: 01MAY01
Title:	Multiple Target Tracking With Out-of-Sequence GMTI/HRR Data
Abstract:	MRLets Technologies, Inc. proposes a new multiple target tracking system which has a strong capability to handle out-of-sequence multi-platform GMTI/HRR radar reports. Recognizing that one of the most important concerns about a GMTI/HRR tracking system is the ability to handle a very large number of tracks in the field of view, this proposal suggests a set of techniques for establishing the right trade-off between tracking performance and requirement on resources. An algorithm is proposed to predict the necessity for adding an out-of-sequence report. Clustering of tracks is suggested in order to decompose the correlation between groups of tracks. This new system is based on Wavelet Feature Aid Tracking (WFAT), which is a novel approach for joint tracking and target recognition. Two key system components for handling out-of-sequence data are a filter with (near) optimal back-propagation capability and a data associator with (near) optimal multiscan report assignment capability. The development starts with analysis of optimal designs. The resulting optimal designs shall form a benchmark system for further performance analysis. Constraints are then added to the optimal designs and practical solutions are obtained. Proof-of-concept simulations are proposed on both the optimal designs and practical designs. It is expected that an effective combination of the trade-off study and practical designs shall render the new tracking system with superior performance, and shall benefit many DoD and non-DoD applications. The proposed GMTI/HRR tracking system will primarily benefit military and aerospace applications, including surveillance/reconnaissance systems for battlefield command and control. It also has great potential in commercial applications, such as highway traffic control and safety systems.

ALPHATECH, INC. 50 Mall Road Burlington, MA 01803
Phone: PI: Topic#:	(781) 273-3388 Dr. Gil Ettinger AF 01-207 Awarded: 14APR01
Title:	Model-Based Fusion of Multiple Look SAR for Automatic Target Recognition
Abstract:	We propose to develop and evaluate robust model-based approaches to combat ID by fusing multi-look SAR imagery of ground vehicles. We have already developed a baseline decision-level multi-look fusion approach, based on the MSTAR system, that accumulates evidence over target type. Extensive evaluation of this multi-look system has indicated significant target identification performance benefits. Under this proposed effort we will develop, implement, and analyze several improvements to the decision-level fusion strategy: (1) hypothesis-level fusion, where we accumulate evidence not only over target type but also of target pose, thereby ensuring consistent interpretation across all the images; and (2) feature-level fusion, where we accumulate evidence over parts of the model, thereby correctly accounting for model region visibility across the multiple views. As we increase the fidelity of the multi-look fusion approach, we also require finer image registration requirements. To support accurate registration we propose to apply our hierarchical pixel/feature/region registration algorithms, which have proved to be effective on related applications. In order to analyze the performance tradeoffs of the different multi-look approaches and understand their benefits and limitations, we will perform extensive analysis on available in-house multi-look MSTAR SAR imagery covering a broad range of operating conditions.The technology developed under this program will contribute directly to the overall military objective of improving automatic combat identification from SAR imagery for a variety of targets and under a variety of conditions. Specifically, multiple look fusion will improve identification performance, reduce false alarm rate, increase robustness against variabilities of target and collection conditions, and achieve fine discrimination among similar targets. We anticipate that these methods could be used to automate SAR peacetime applications such as treaty compliance assessment and monitoring. Moreover, model-based multi-look fusion techniques could be used for law enforcement applications as well as disease detection and diagnosis in 2D medical imagery.

ORINCON CORP. 9363 Towne Centre Drive San Diego, CA 92121
Phone: PI: Topic#:	(858) 455-5530 Mr. Timothy Zadra AF 01-208 Awarded: 18APR01
Title:	Tracking Densely Spaced Ground Targets with Data Fused from Moving Target Indication Radar
Abstract:	Integration of ORINCON's Ground Moving Target Indicator (GMTI) tracking algorithms into a parallel processing software data fusion architecture is proposed. The GMTI tracking algorithms incorporate Variable Structure Interacting Multiple Models (VS-IMM) that enable precision tracking of highly maneuverable ground targets. An innovative data fusion architecture incorporates parallel processing that replicates common tracking and fusion processes to run across a scalable number of array processors within a COTS VME-based architecture. Integrating the ground-based tracking algorithms into the parallel fusion architecture enables a hardware-scalable solution to the centralized GMTI data fusion and tracking problem. By adding processor cards, throughput can be scaled up to meet increasing requirements for additional targets and sensors with no software modifications required. A dedicated fusion management process automatically distributes the processing load evenly across the configured processing nodes. Data association is carried out under a strict multiple-hypothesis framework. The resource management of the array processor nodes is dynamic within the limitations of the number of physical processor nodes configured within the VME chassis.Centralized processing locations such as JSTARS ground stations can benefit from this capability. Users require a system that can fuse data from multiple sensor platforms and process 5,000 to 10,000 targets in real time. The parallel processing-based GMTI tracking system will enable this type of performance and beyond.

DEFENSE RESEARCH ASSOC., INC. 1430 Oak Court, Suite 303 Beavercreek, OH 45430
Phone: PI: Topic#:	(937) 431-1644 Mr. Ronald Clericus AF 01-209 Awarded: 01MAY01
Title:	Evolving Onboard/Offboard Electronic Warfare Technology
Abstract:	Advanced sensor and electronic warfare technologies are being applied to both airborne (manned and Unmanned Air vehicles (UAV)) and space assets. Current research and development methodologies that evolve these technologies are time-consuming and require extensive/costly testing on open air ranges. Open air ranges cannot generate the dense threat emitter environments that would be experienced in actual combat situations. Flight test productivity is low due to the fact that there are so many uncontrolled variables and the inability to make changes during the actual flight test. The current simulation technologies do not have the required fidelity and real-time DoD High Level Architecture (HLA) simulation support environment for rapid prototyping of onboard/offboard sensor and electronic warfare capabilities. These limitations must be overcome if the DoD HLA concepts/requirements being sponsored by the Defense Modeling and Simulation Office (DMSO) are to become a reality in the defense community. This research addresses the incorporation of HLA standards per the DMSO M&S Master Plan. Defense research Associates (DRA) will develop an innovative integration tool set to support evaluation of onboard/offboard sensor systems in a robust simulation (laboratory) environment. DRA will utilize the real-time simulation capability in the Sensors Directorate Integrated Demonstrations and Applications Laboratory (IDAL) to demonstrate the architecture's feasibility. During Phase II, DRA will implement a prototype capability into the IDAL and demonstrate key performance characteristics. The Phase II effort will provide a building block capability for rapid evolution of advanced RF sensor technology.The Phase I/II SBIR results shall provide a real-time high fidelity dense RF environment simulation base that will address the needs of evolving advanced RF sensor systems. This simulation technology base will be leveraged to provide RF simulation products resulting in Phase III initiatives that address both government and commercial applications

MACAULAY-BROWN, INC. 4021 Executive Dr. Dayton, OH 45430
Phone: PI: Topic#:	(937) 426-3421 Mr. Rodger Southworth AF 01-209 Awarded: 03MAY01
Title:	Evolving Onboard/Offboard Electronic Warfare Technology
Abstract:	The capability to precisely locate and identify radio frequency (RF) threats in real time is critical for warfighter system-of-systems environments that utilize multiple sensors. Developmental radar warning sensors such as the Precision Location and Identification (PLAID) and special receiver collection systems determine precise threat location or identity by making extremely accurate parameter measurements of Doppler/phase shifts, angle-of-arrival (AOA), and time difference of arrival (TDOA). Open-air ranges cannot provide dense emitter environments, nor the controlled, repeatable conditions essential for valid and affordable testing. Current DoD laboratory testing facilities and commercial simulators cannot simulate all the detailed, fine grain signal characteristics required to effectively test PLAID technologies. Innovative simulation concepts are required that can generate appropriate RF signal modulations with an accuracy/resolution exceeding the measurement capability of PLAID sensors. This Phase 1 SBIR will develop a creative design concept called the Advanced TDOA, AOA, and Phase (ATAP) threat simulation that addresses the critical technology challenges of testing PLAID sensors. The ATAP design will be implemented and demonstrated in the AFRL/SN Integrated Demonstrations and Applications Laboratory (IDAL) in the Phase 2 SBIR program. Phase 1 will result in a simulator design, readily convertible to prototype hardware during Phase 2. ATAP will have a high payoff by reducing development risk and testing cost by enabling rapid prototyping of hardware design and software algorithms in a controlled environment. ATAP is readily adaptable to commercial Automated Test Equipment (ATE) applications for the communications industry to test Air Traffic Control systems, Microwave Landing Systems (MLS), cellular telephones, point-to-point microwave, Global Positioning (GPS), and VHF and UHF communications systems. It can also be employed by DoD contractors as a commercial tool for testing passive and active ECM and ESM systems in B-1, B-2, F-15, F-16, U2, F-117, F-22 and JSF integration laboratories. By the addition of high power amplifiers and high gain antenna systems, ATAP becomes suitable for range installation, and has applications in both free space range testing, and electronic warfare combat simulation and training applications.

NAVSYS CORP. 14960 Woodcarver Road Colorado Springs, CO 80921
Phone: PI: Topic#:	(719) 481-4877 Ms. Alison Brown AF 01-210 Awarded: 25APR01
Title:	GPS/IMU Ultra-Tightly Coupled Integrity Monitoring
Abstract:	Global Positioning System (GPS) applications which involve safety-of-flight operations (e.g. precision and non-precision instrument landing) require integrity monitoring. Previous integrity monitoring techniques implemented took advantage of redundant observations (e.g. Receiver Autonomous Integrity Monitoring or RAIM) or off board resources such as wide area or local area augmentation. Recent advances have led to the development of ultra-tightly coupled GPS/inertial solutions that provide significantly improved performance in the presence of signal interference. In this proposal, an ultra-tightly coupled (UTC) GPS/inertial (GI) integrity monitoring solution is proposed that enables robust detection, identification and rejection of failed GPS observations from the coupled GPS/inertial navigation solution. Under the Phase I effort, the UTC- GI Integrity Monitoring algorithm theory will be further developed and documented. The performance of the algorithm under simulated satellite failure conditions will be demonstrated using data collected from in-house GPS/inertial test equipment. Under the Phase II effort, we propose to delver an Ultra-Tightly-Coupled GPS/Inertial integrated system that can be demonstrated to meet FAA's RNP integrity requirements and also provide robust navigation capability in the presence of jamming. Applications exist for leveraging the improved integrity monitoring, A/J performance and high accuracy provided by the Ultra-Tightly-Coupled GPS/Inertial Integrity solution for both civil and military precision approach and landing systems, such as LAAS or JPALS.

ZC&H DYNAMIC SYSTEMS, INC. 102 San Mateo Terrace Cedar Park, TX 78613
Phone: PI: Topic#:	(512) 794-2804 Mr. James Chaffee AF 01-210 Awarded: 18APR01
Title:	Decoupling Approach to Ultra-Tight Coupling
Abstract:	Three simple, direct methods for decoupling the interrelated channel outputs in an ultra-tightly coupled GPS/IMU system are proposed. These methods, based on conditioning, are not as computationally expensive as methods such as multiple model matching, and also take advantage of the high precision of carrier phase measurements and the presence of the IMU.The commercial potential for this technology includes both military and commercial aircraft. Military programs such as JPALS, along with similar civil aviation programs, are expected to be potential customers.

MISSION RESEARCH CORP. Post Office Drawer 719, 735 State Street Santa Barbara, CA 93102
Phone: PI: Topic#:	(937) 429-9261 Dr. Byron M. Welsh AF 01-211 Awarded: 01MAY01
Title:	Adaptive Array Processing for Targeting Radar Application
Abstract:	There are a number of key issues faced in performing ground moving target detection, velocity estimation and DOA estimation from an airborne radar system. These issues include effective suppression of clutter and interference in a scenario in which conventional secondary data requirements may be prohibitive. They also accurate DOA estimation in the presence of unavoidable array calibration errors as well as optimally processing wideband data to achieve the most efficient parameter estimation and target detection while at the same time preserving the information content in the wideband data. Our approach for addressing each of these key problems is based on 1) developing optimal statistical processing-based algorithms for performing both the moving target detection problem and the target parameter estimation problem (velocity and direction of arrival); 2) developing a simulation environment for generating realistic radar signature data to test the algorithms; and 3) rigorously quantifying algorithm performance using the simulation environment and Monte-Carlo simulations.Commercial benefits of the proposed research include all applications of detection and identification of moving targets using high resolution radar systems. These applications include detection and tracking of planes and ground vehicles at airports for safety purposes, detecting and tracking of cars and trucks on highways for track flow analysis and safety, detection and tracking of intruders and non-intruders for building surveillance, detection and tracking of cargo handlers (fork lifts, trucks, people) in a large, congested warehouse environment for safety and efficiency, and detecting and tracking moving parts within a manufacturing plant for monitoring and controlling the manufacturing process. We anticipate that the need to track and to identify a large number of targets in a diverse set of environments (like those mentioned above) will grow significantly as the adaptive signal and array processing capability improves to the point that clutter and interference are effectively mitigated and target parameters can be reliably estimated. The benefit of such a capability will impact all the commercial applications discussed above simply by making such a capability a reality.

APPLIED OPTIMIZATION, INC. 8801 Windbluff Point Centerville, OH 45458
Phone: PI: Topic#:	(937) 439-1220 Mr. Anil Chaudhary AF 01-213 Selected for Award
Title:	Calibration of Space-Based Sensors and Unknown Target Signature Separation
Abstract:	Applied Optimization, Inc. proposes a three-step approach for identifying the unknown physical characteristics of a target satellite based on its multi-spectral point image. In the first step, a method is proposed for calibrating space-based passive sensors using data from tracking a Navstar satellite. The specific data to be used was obtained by an experiment aboard the MSX satellite. There are two advantages to this approach, namely; the Navstar position is known precisely, and a constellation of twenty-four satellites is always available for tracking. The second step considers that Navstar characteristics were unknown and represents them as a Boolean of geometry primitives and a set of surface properties. Its point image is expressed as a sum of several contributions that arise as the spacecraft swivels to manage the pointing of its antenna cluster and solar panels. Then the visual and infrared spectrum data is fused to solve for unknown characteristics. The third stage considers that the target could be represented as a Boolean of unknown geometry primitives, which can be crossed-over and mutated to match the multi-spectral point image. A Genetic Algorithm is proposed to create the different possibilities and decode the components in the unknown target signature.DoD Benefits: [1] A process for calibration of passive sensors using mono tracking data. [2] Reduction of time between detection and decoding of an unknown target. Applications: [DoD] Separation of unknown signature for ballistic missile targets. [Commercial] Analysis of Measurements for Highway Traffic Signature Separation.

AGILTRON CORP. 20 Arbor Lane Winchester, MA 01890
Phone: PI: Topic#:	(781) 933-0513 Dr. Jing Zhao AF 01-215 Selected for Award
Title:	Low loss, polarization insensitive, high speed fiber optic switch
Abstract:	High performance fiberoptic switches are in great demand for use in optical communication networks and modern defense systems. Current fiberoptic switches do not simultaneously meet the requirements of high speed, low loss, high extinction ratio, and high reliability. Based on the successful development of a state-of-the-art high speed and highly stable 1x1 switch, Agiltron Corporation proposes to fabricate a novel solid-state 1x2 switch, using electro-optical crystals with large electro-optic effect and excellent thermal stability. This fiberoptic switch has leading edge performance attributes, which include electro-optic high-speed operation, polarization insensitivity and low optical insertion loss, as well as crystal ruggedness for high optical power handling and long-term stability. The design eliminates the need for mechanical movement, organic materials, and waveguides, which introduce intrinsic drawbacks. Moreover, the design is simple, compact, and cost effective. It is anticipated that state-of-the-art performance in several key specifications can be achieved through this program. These include both optical performance and reliability, as well as cost effectiveness. Prototype electro-optic 1x2 switches will be fabricated to demonstrate functionality in Phase I. 2x2 version will be produced in Phase II.It is anticipated that the proposed high performance switch will have wide application in DoD systems such as photonic radar and fiberoptic microwave distribution network. The anticipated commercial communication switching market is very large with forecasted reaching billion dollars by year 2006.

WINDMILL INTERNATIONAL, INC. 2 Robinson Road Nashua, NH 03060
Phone: PI: Topic#:	(603) 888-5502 Mr. David W. Martin AF 01-216 Selected for Award
Title:	Disposable Tactical Satellite Antenna System
Abstract:	This Phase I effort will investigate and determine the feasibility of procuring and modifying commercially-available satellite dishes for use as Tactical User Antennae for access to tactical satellite information. If feasible, this would provide DoD with an extremely low-cost solution to the stated objective and result in tactical flexibility - the ability to abandon these antennas, if necessary, with no concern for the expense of the equipment.Primary application is as a disposable antenna for use in military applications. Besides the Air Force, this antenna design would be useful particularly to special operations, quick reaction, or light infantry forces in the Navy, Army, and Marine Corps. Low cost, displosable satellite downlink antennae can also be used for remote research posts.

RF NITRO COMMUNICATIONS, INC. 10420 Harris Oaks Boulevard, Suite F Charlotte, NC 28269
Phone: PI: Topic#:	(704) 596-9060 Mr. Jeffrey B. Shealy AF 01-217 Selected for Award
Title:	Space Qualified GaN Communication Technology
Abstract:	We propose to investigate wide band gap Gallium Nitride (GaN)semiconductors for K-band and Ka-Band power applications for high reliability spacecraft as well as commercial communications. High electron velocity in AlGaN/GaN heterostructure devices indicate significant potential for fabrication of mm-wave HFET devices. RF output power of 10-12 W/mm with power-added efficiency approaching the ideal values for class A and B operation is available from AlGaN/GaN HFETs up through 30 GHz. Single device (4W) high power amplifiers are projected with high efficiency (exceeding 50%) are projected in phase I. High temperature life-test of amplifiers built during phase I will be examined to predict MTTF at conventional temperatures as well as at elevated operating temperatures. Key attributes to achieving reliability on GaN include a stable passivation technology (to eliminate gate lag), stable gate technology (to achieve high breakdown voltage), and proper heating sinking (to achieve optimal channel temperatures).(1) Ultra high power internally matched FETs, (2) Ultra high power MMICs, (3) High IP3 driver amplifiers, (4) Base station amplifiers, (5) High Power handling distribution switches, (6) High temperature sensors for automotive and aircraft engines.

KYMA TECHNOLOGIES, INC. 8829 Midway West Road Raleigh, NC 27613
Phone: PI: Topic#:	(919) 789-8880 Dr. Drew Hanser AF 01-218 Awarded: 01MAY01
Title:	Multiple Frequency GaN FETs on Aluminum Nitride Substrates
Abstract:	This program will develop high power, multiple frequency RF switches utilizing AlN substrates developed by Kyma Technologies, Inc. High-performance GaN-based devices, such as microwave transistors, have been demonstrated on sapphire and silicon carbide substrates; however, defects due to lattice and thermal expansion mismatch limit device performance. Dislocations significantly affect the performance of electronic devices by reducing carrier mobility, increasing noise and gate leakages, and cause premature device breakdown. Aluminum nitride substrates are expected to improve the performance of GaN-based microelectronic devices due to close lattice and thermal expansion match with GaN-based device structures. Additionally, AlN substrates are well suited to high frequency switching device applications due to their insulating nature and high thermal conductivity. Using Kyma Technologies, Inc.'s demonstrated AlN substrate technologies, high-power GaN-based switches for space-based applications will be developed. This research and development effort will address issues in devices related to high-power handling and isolation, fast switching time and low insertion loss. Creating devices with these characteristics will be achieved by taking advantage of the unique properties of the AlN substrates produced by Kyma Technologies, Inc.The results of the program will benefit both satellite and terrestrial wireless communication systems. The use of an aluminum nitride substrate in microelectronic applications will decrease the time to market for these devices. FETs developed in this project will have higher power handling and isolation, fast switching times, and low insertion losses. Commercial applications of GaN-based multiple frequency FETs include portable electronics, linear high frequency power amplifiers, space-based systems, automotive electronics, and high temperature microelectronics.

EMAG TECHNOLOGIES, INC. 3055 Plymouth Road, Suite 205 Ann Arbor, MI 48105
Phone: PI: Topic#:	(734) 747-6646 Dr. Tayfun Ozdemir AF 01-220 Awarded: 09APR01
Title:	MEMS-Switched Reconfigurable Antenna
Abstract:	The objective of this SBIR Phase I project is to explore and design novel reconfigurable antennas with multi-band operation and pattern control capability. The first proposed element combines a multi-band stacked patch configuration with switchable patch clusters, and the other consists of a reconfigurable slot antenna. Both elements utilize MEMS structures as switching devices. The phase I feasibility study involves design, modeling and parametric study of each of the elements with limited experimental investigation. The fabrication and testing of the elements and design of arrays of them are relegated to the Phase II continuation of this project.The reconfigurable antennas resulting from this project have numerous applications in multi-function and multi-band communication systems as well as military sensing, command and control systems.

MISSION RESEARCH CORP. Post Office Drawer 719, 735 State Street Santa Barbara, CA 93102
Phone: PI: Topic#:	(937) 429-9261 Mr. Thomas M. Fitzgerald AF 01-221 Awarded: 23APR01
Title:	Hyperspectral Resolution Enhancement
Abstract:	Hyperspectral imagery represents the latest and most advanced tool for remote sensing. A hyperspectral data cube presents a vast range of spatial, spectral, and temporal information to the operator. Hyperspectral imagery is finding vast markets in such disparate fields as military intelligence, tactical military operations, geology, forestry, cultural studies, and environmental studies. However, a trained imagery analyst may be disappointed with the resolution of hyper-spectral imagery (HSI). Mission Research Corporation proposes the use of co-registered high-resolution broadband imagery coupled with the known system Point Spread Function (PSF) in an optimized Maximum A Posteriori (MAP) Estimator to improve the resolution of the hyperspectral imagery beyond current limitations. We propose that the high-resolution broadband imagery will also be improved using our current MAP techniques before it is used to improve the hyperspectral data. Our initial results are very promising and are included in the proposal. The processing cost for computers required to perform the computationally intensive MAP routines is on an exponential downward curve. This reduced cost factor makes computationally intensive solutions such as MAP attractive.The advent of high-density focal plane arrays has allowed for the manufacture of high-resolution imaging systems. The imaging systems are being increasingly employed by the DoD as they incorporate more and more electro-optics technology in sophisticated military systems. Digital imaging technology is being used for night vision, targeting, target recognition, surveillance and tracking. All of these functions are extremely critical for the successful deployment and mission accomplishment of current military systems. Most of these systems offer a "digital zooming" feature which is based on simple interpolation schemes. The algorithms and hardware developed over the course of this program to overcome the deleterious effects of resolution for hyperspectral imaging are critical for realizing the full potential of the resolution of digital imaging systems. The market size for the Air Force alone is directly proportional to the large number of aircraft employing infrared imaging technology such as LANTIRN pods. Within the private sector, imaging systems (both visible and infrared) are increasingly being used for night vision, surveillance and security, and personal photography. Just as the DoD can benefit from enhanced imagery for data exploitation purposes, the private sector can also benefit. Improving the image quality produced by imaging systems will inherently make these systems more attractive for applications requiring high quality and high-resolution imagery. Sceurity systems are a particularly good example of a large market that would benefit significantly from the capability to produce enhanced imagery that reduces image distortion as well as enhance image resolution. Many security systems involve both infrared and visible imaging capabilities. The images produced by these systems are often blurred and distorted due to the effects of camera motion and jitter as well as the poor inherent resolution of the array (e.g. undersampling effects of a CCD) used to capture the raw image. The MAP estimator solution proposed here has important applicability to enhancing the distorted and blurred image produced by these imaging systems.

PHOTON RESEARCH ASSOC., INC. 5720 Oberlin Drive San Diego, CA 92121
Phone: PI: Topic#:	(256) 536-2428 Mr. Paul Cox AF 01-221 Awarded: 19APR01
Title:	Hyperspectral Resolution Enhancement with Support Vector Machines
Abstract:	With the continued growth of hyperspectral sensor technology for both military and commercial applications, there is an ever-increasing need to make the maximum use of data from these devices. Despite the wealth of information that can be extracted from hyperspectral cubes, additional information could be extracted if these devices had better spatial resolution. The resolution of these devices is inherently limited by physical constraints (cost, size, and manufacturing). To overcome this limitation, Photon Research Associates (PRA) proposes a unique signal processing approach which combines the proven mathematics of wavelet denoising along with Support Vector Machines (SVM) for resolution enhancement of the hyperspectral data. Support Vector Machines are based on the field of mathematics called Statistical Learning Theory develop by Vapnik at Bell Labs. SVMs have been proven to be superior to classical techniques and have been applied successfully to various application areas including pattern recognition, regression, and estimation for real valued data. We propose to extend the theory and apply SVMs for estimating and extracting the higher spatial frequencies and hence providing resolution enhancement of the hyperspectral data.The results of this SBIR can be applied commercial and military hyperspectral remote sensing systems in order to improve its resolution beyond the diffraction limit. Potential military applications include target/anomaly detection, site monitoring, and trafficability analysis. Potential commercial applications include remote sensing for geological, land use monitoring, agricultural, environmental monitoring, and mineral exploration purposes.

SURFACE OPTICS CORP. 11555 Rancho Bernardo Road San Diego, CA 92127
Phone: PI: Topic#:	(858) 675-7404 Mr. Mark S. Dombrowski AF 01-221 Awarded: 19APR01
Title:	Hyperspectral Resolution Enhancement
Abstract:	The objective of the Phase I Fast Track SBIR is to develop novel HSI sensor and signal processing techniques for enhancing the spatial resolution content of HS imagery. Due to the importance of the effort, SOC has identified a qualified Phase II partner to support our effort. The SOC team including SSI, V-EI and CEB Metasystems has identified, developed and evaluated several novel, workable HSI resolution enhancement techniques under other activities, e.g., H/SIP, which have been designed to preserve the spectral radiometric fidelity of the spectral signatures so as to support automated post processing via the MIDIS real-time HSI processor for applications such as JOANNA. To satisfy the objectives of the Phase I program, the SOC team will conduct the following tasks: (1) Develop HSI resolution enhancement techniques; (2) Develop techniques evaluation and ranking criteria; (3) Conduct techniques modeling and simulation analysis; (4) Determine techniques performance; (5) Define techniques development and demonstration plan; (6) Identify potential sources of capital for commercialization; and (7) Provide reporting. Successful completion of these tasks will satisfy the objective of our proposed program, "to develop novel HSI sensor and signal processing techniques for enhancing the spatial resolution content of HS imagery", by utilizing the available MIDIS technology for development and demonstration of promising techniques. The MIDIS 2000P HSI video processor and a VIS/NIR MIDIS 2000V and LWIR MIDIS 2000L real-time HSI sensor modules are being delivered to the AFRL under the TWARS project. This SOC commerical technology will be utilized during the planned Phase II effort to develop, test and demonstrate promising HS resolution enhancement techniques. By building on the SOC team's decades of experience in real-time HSI systems and technology development including resolution enhancement techniques, our proposed program will provide the technology data base to be able to design and develop the next generation real-time enhanced spatial resolution instruments, benefiting not only the Air Force, but also industry. Techniques developed under this topic would allow the extraction of enhanced spatial resolution information from a range of planned commercial HS remote sensing systems for both commercial and military applications. Potential military applications include LO target detection and terrain/trafficability analysis. Potential commerical applications include remote sensing for geological, land use monitoring, agricultural, and mineral exploration purposes.

TECHNICAL RESEARCH ASSOC., INC. 760 Las Posas Rd., Suite A-4 Camarillo, CA 93010
Phone: PI: Topic#:	(805) 987-1972 Dr. Edwin M. Winter AF 01-221 Awarded: 26APR01
Title:	Hyperspectral Resolution Enhancement
Abstract:	The proposed work will demonstrate a new and innovative technique for improving the spatial resolution of hyperspectral image data. This technique, called Joint Endmember Determination and Unmixing, promises to combine a high-resolution panchromatic image with a lower spatial resolution hyperspectral image to produce a product that has the spectral properties of the hyperspectral image at a spatial resolution approaching that of the panchromatic image. The result is not just a panchromatic image that has been "colorized" by the HSI image, but a true analysis product that can be used for subsequent hyperspectral processing. The proposed approach is based on the application of linear unmixing to an image cube that is constructed from registered high spatial resolution and high spectral resolution image cubes collected from the same scene. This is a departure from procedures that have been implemented before, and offers the benefits of high spatial and spectral resolution for subsequent hyperspectral processing. Under Phase I, the Joint Endmember Determination and Unmixing Algorithm and required high quality registration procedures will be developed. Tests will be conducted on image data collected from airborne platforms with both high resolution panchromatic and hyperspectral sensors.Hyperspectral imaging systems are assuming a greater importance for a wide variety of commercial and military systems. The reason for this increased interest is the fact that a hyperspectral sensor of a given spatial resolution or pixel size will reveal information on the scene that are not obtainable by single band or multi-spectral sensors. For commercial geological remote sensing, the spectral properties of the surface will tell the existence of minerals of potential commercial value. For military surveillance systems, the hyperspectral system can often be used to detect and identify a military target, even though there may be less than a pixel resolved on the target. The ability of the hyperspectral sensor to behave as a sensor with "super-resolution" does not mean that there is not a place for high resolution imagery. In fact, many operational and planned hyperspectral sensors are coupled with a high resolution instrument. In some concepts, this high resolution sensor is used as part of a detection process. The Adaptive Spectral Reconnaissance Program (ASRP) sensor demonstration is one such example where the hyperspectral sensor was used for wide area search and each detection was then confirmed by a panchromatic imager. The same combination of sensors is true for commercial and intelligence sensor systems. For example, the NASA Hyperion, Air Force Warfighter and Navy NEMO satellites will have both a high resolution panchromatic sensor and a hyperspectral sensor. There are many applications for a technology that can optimally combine the data from these two types of sensors. An existing procedure called "sharpening" combines the output of the analysis of the hyperspectral data with the high resolution image. The proposed procedure is superior to that approach and will have a variety of military and commercial benefits. There are two military applications: target detection and scene classification. Military concepts with both a high resolution imager and a hyperspectral include: ASRP, COMPASS, WAR HORSE, SPIRITT. Most plan on using the sensors serially: initial detection decision on hyperspectral followed by confirmation with the panchromatic. Processing of the data from the two sensors together will result in high probabilities of detection and lower false alarm rates. For the scene classification application, which is used for terrain trafficability as well as intelligence, the development of image products with the properties of both sensors will aid the work of the Image Analyst. TRA, as early as Phase I, will be investigating these areas for potential future application There are multiple potential uses for commercial hyperspectral. Satellite hyperspectral remote sensing products are limited in spatial resolution by the constraints of a space-base optical system and the great range to the scene. TRA is already talking to the commercial companies involved in the Hyperion and NEMO satellite systems. The processing requirement is very important here and our program plan includes determining hardware and software solutions to the processing problem. The market timing for this effort is ideal because: 1). Within the next two years, at least three hyperspectral sensors, along with a panchromatic imager, will be delivering data. 2). Military surveillance technology employing this combination of sensors is being investigated in all three branches of the military for a variety of applications. This proposed program represents a key opportunity to develop a new technology with high likelihood potential for commercial success, that also has high promise for the United States military.

ASTRALUX, INC. 2500 Central Ave. Boulder, CO 80301
Phone: PI: Topic#:	(303) 413-1440 Dr. John T. Torvik AF 01-222 Awarded: 25APR01
Title:	Silicon Carbide Power Transistors for High Power Transmitter
Abstract:	Astralux, in collaboration with the University of Colorado, proposes to develop high-power SiC microwave bipolar transistors for use in pulsed RF transmitters. More specifically, the performance goal is a 4H-SiC bipolar junction transistor (BJT) with pulsed power up to 650 W, single stage power gain up to 12 dB and bandwidth up to 3 GHz. The advantages of bipolar devices over Si-based devices include power gain, superior linearity and stability combined with a higher power dissipation capability. Compared to other SiC devices, the BJT provides better power added efficiency, higher power gain and superior linearity while operating on a single supply voltage, leading to more compact and cost efficient systems.SiC BJTs are identified as potential high-power microwave devices and would greatly benefit the development of high-power transmitters and wireless communication.

UNITED SILICON CARBIDE, INC. New Brunswick Technol. Center, 100 Jersey Ave. Bui New Brunswick, NJ 08901
Phone: PI: Topic#:	(732) 565-9500 Mr. Petre Alexandrov AF 01-222 Awarded: 26APR01
Title:	Design and Fabrication of An Advanced SiC SIT for High Power Transmitter
Abstract:	In response to Air Force SBIR Topic No. AF01-222, we propose to design and fabricate advanced SiC SITs based on advanced SiC process technology. The advanced design is expected to lead to (i) substantially reduced complexity in the process and fabrication of SiC SITs, both in critical alignment requirements and in gating structure formation; and (ii) greatly improved signal output stability, efficiency, power density, and high temperature capability. In Phase I, we propose to design, optimize, and compare three different SiC SIT structures including an inverted mode SIT. DC and high frequency characteristics will be systematically studied both at room temperature and 300C. Concentration will be focused on normally-off operation with highest possible power density, efficiency, and bandwidth over a wide temperature range. We also propose to perform experimental work to develop all of the critical process technologies in Phase I. In Phase II, we shall apply the developed technology to fabricate the advanced 4H-SiC SITs and use them to demonstrate the operation of a prototype pulsed transmitter capable of stable output signals at temperatures up to 300 C range. High performance SiC SITs for high frequency, high power and high temperature applications including airborne and space pulsed power transmitters and wireless communication base stations and satellite links.

JRM ENTERPRISES, INC. 1 Hemlock Court, Suite 1A Fredericksburg, VA 22407
Phone: PI: Topic#:	(540) 785-4585 Mr. Joseph R. Moulton, Jr. AF 01-224 Awarded: 25APR01
Title:	A Robust Spectral Scene Generation Capability to Support Advanced Sensor Concepts and Algorithms
Abstract:	JRM Technologies, Inc., in conjunction with Terrex and CG2, proposes to develop a low-cost, physics-based spectral scene generator as a reliable alternative to field data collection for the development and evaluation of advanced hyper/multi-spectral sensor concepts and associated signal processing algorithms. In Phase I, JRM will develop a scene generator design for a Phase II implementation that addresses cost-effective database generation, realistically complex clutter modeling, physics-based spectral signature and atmospheric synthesis, and optical sensor effects simulation. To ensure the completeness of the approach, the Phase I effort will also include a rigorous requirements definition and thorough validation plan.The technologies to be developed as part of this effort have very broad Phase III commercial application, particularly in the field of remote sensing for natural material identification and earth surface assessments. A low-cost spectral scene simulator would provide industry a crucial technology component for remote-sensing algorithm improvement test-beds, and a catalyst for substantially improved GIS products for geology, land use monitoring, agricultural, and mineral exploration.

PHOTON RESEARCH ASSOC., INC. 5720 Oberlin Drive San Diego, CA 92121
Phone: PI: Topic#:	(505) 888-2858 Mr. Bruce Shetler AF 01-224 Awarded: 25APR01
Title:	Innovative Approaches to Scene Database Construction
Abstract:	Simulation is a critically important tool for many aspects of electro-optical systems engineering including performance evaluation, test support and training. A common problem is encountered in that the raw sensor data used to generate simulation databases is often of a lower resolution than the objective system. An improved technique to generate high resolution geo-specific databases for multi and hyperspectral scene simulation is proposed. The technique employs multi-resolution data and a novel sharpening approach to create simulation databases with realistic background clutter content at high spatial resolution.Modeling and simulation (M&S) are increasingly applied to the design and engineering of spectral and hyperspectral electro-optical sensing systems, but this effort may serve to galvanize the use of these techniques at a particularly significant point of commercial impact. Currently, Photon Research Associates occupies a favorable position in this market, having a set of simulation capabilities which are nearly unique in the United States. However, growth in this area has been limited by two factors: First has been the slow adoption of M&S technology by sensor designers - in a hardware dominated field, the design process has been focused on hardware related issues (eg; SNR, NEDT, NEDr, spectral resolution, etc) with less consideration given to performance as taken in a end-to-end context including back-end exploitation performance. Second, M&S has failed to sufficiently prove itself as a reliable indicator of performance across the board and M&S development has lagged the development of increasingly sophisticated hardware. In essence, M&S which should be expected to lead the design process and which should be seen to play and expanded role, particularly in military affairs, as the worldwide democratization of sensing brings added emphasis to exploitation processing, has failed to develop at a sufficiently rapid pace to assume the role it should have. This project will serve to address both of these issues, by providing technology which can increase the fidelity and utility of M&S based systems engineering processes and by simultaneously facilitating the propagation of more sophisticated M&S technology into the EO design community. Market timing is ideal because: (1) the design and acquisition process is becoming overwhelmed by the complexity of systems which can be conceived - the problem (especially for acquisition versus research programs) is now much more one of which system should be built, rather than which system can be built; (2) the "democratization of sensing" mentioned above will mean that for both commercial and military acquisition entities, it will become absolutely critical for sensor systems to be considered in a complete systems context. As the playing field for primary data acquisition becomes level and the true worth of a system can only be understood in an exploitation and dissemination context, only sophisticated M&S can address these larger design issues before development proceeds; and (3) PRA has a unique market position in that we are the only purveyors of the unique geo-specific terrain based simulation capabilities which we have pioneered and developed over the course of nearly 20 years. Technical Research Associates has been a partner in this development from the beginning and the new sophistication in terrain modeling which will be developed under this program will put our team in an ideal position to exploit this market. In a larger sense, however, we should recognize that this program represents a key opportunity for the Government-Industry partnership to succeed by moving forward a new technology which meets SBIR criteria via a clear and high likelihood potential for commercial success, but which will also provide unique new capabilities to benefit National security and enhance the competitive advantage of the U.S. commercial remote sensing industrial base.

SPECTRAL SCIENCES, INC. 99 South Bedford Street, Suite 7 Burlington, MA 01803
Phone: PI: Topic#:	(781) 273-4770 Dr. Steven Richtsmeier AF 01-224 Awarded: 25APR01
Title:	Hyperspectral Scene Simulation in the Ultraviolet Through Longwave Infrared
Abstract:	Efficient design of remote sensors, including both the optics and data processing algorithms, depends critically on the availability of well characterized data spanning the operational space of interest. It is not practical to span this space with field data alone and requires extensive use of scene simulations to leverage limited field collects into the wide range of anticipated measurement conditions. Spectral Sciences, Inc. proposes to develop a hyperspectral (HSI) scene simulator covering the ultraviolet/visible (UV/VIS) through thermal infrared (TIR) spectral region (~0.4-14 �m) which applies to airborne and spaceborne sensors and nadir and off-nadir viewing. The overall Phase I objective is to develop and demonstrate a UV/VIS-TIR HSI simulation methodology capable of generating statistically (i.e., spectral and spatial) realistic scenes based on GIS (Global Information System) scene descriptors (e.g., surface elevation and material type). Phase I will feature new methods for extraction of material spectral and spatial statistics from HSI data, and the use of these statistically defined materials to construct simulated scenes. Phase II will feature full implementation of the new capabilities developed in Phase I as well as extensive validation and analysis against a wide variety of HSI sensors and data sets. The commercial product will be an ultraviolet through longwave infrared scene simulation software package for use by hyperspectral imaging researchers for algorithm development and validation as well as by sensor designers for the multitude of hyperspectral and multi-spectral satellite and airborne sensors under development by DOD, NASA, and commercial companies. The simulation software will support a diverse range of military and commercial applications such as target detection and identification, precision agriculture, mineral exploration, forest and land management, ocean resource mapping, and surface pollution detection.

TECHNOLOGY SERVICE CORP. 11400 West Olympic Blvd., Suite 300 Los Angeles, CA 90064
Phone: PI: Topic#:	(310) 954-2200 Dr. Uri Bernstein AF 01-224 Awarded: 25APR01
Title:	Synthetic Spectral Scene Simulator
Abstract:	Increasing application of hyperspectral imaging (HSI) sensors requires end-to-end sensor simulations to test sensor designs for varying environments and target scenes. One component of an HSI simulation is a synthetic scene simulator that generates simulated radiance images in the sensor's hyperspectral bands. This proposal outlines a design for a HSI scene simulator based on fundamental physics models for reflected and emitted radiance, and using commercial-off-the-shelf image formation tools to generate a radiance image. The simulator accepts synthetic or geospecific terrain data in several standard formats; data is assumed to consist of digital elevation maps and material maps. The latter are usually derived from RGB or multispectral imaging data. Outgoing radiance is computed for each scene element, where an element is typically a terrain material map pixel, or a target facet. The directional dependence of the radiance is given by a wavelength-dependent bidirectional reflectance distribution function (BRDF). The simulated radiance image cube at the sensor is formed using one of several advanced commercial-off-the-shelf imaging libraries with programmable BRDF. In additional to model and algorithm development, Phase I includes tasks to survey user requirements, validate the models and algorithms, specify the external interfaces to the simulator, and perform the preliminary design for the Phase II prototype. The HSI scene simulator will facilitate the development and application of hyperspectral remote sensing. It will predict the performance of a sensor under a spectrum of environmental conditions, terrain cover types, and targets. The HSI scene simulator will be particularly useful in the development of sensors and algorithms for concealed target detection. It maximizes the use of standard terrain data formats and COTS graphics technology, thus providing an efficient and portable tool for hyperspectral and multispectral simulation.

EAGLEWARE CORP. 635 Pinnacle Court Norcross, GA 30071
Phone: PI: Topic#:	(678) 291-0995 Glenn Parker AF 01-225 Awarded: 01MAY01
Title:	RF Synthesis for Wireless Communication, Intellience, Surveillance, and Reconnaissance (ISR) Systems
Abstract:	As a recognized leader in computer-aided synthesis and simulation of microwave and RF electronics, Eagleware Corporation is interested in further developing and expanding its present offering of RF/microwave software tools. At present, RF tools are limited primarily to linear circuits. Also, available software is essentially limited to "point tools," or software suitable for only one or two types of circuits. Engineers would benefit from a software package for the integrated synthesis and simulation of RF and microwave systems. Included with this package should be a seamless flow from system design to physical realization. Eagleware has a range of products already available including filter synthesis, matching networks and oscillator synthesis. Eagleware's vision is an integrated synthesis and simulation environment for component and system level design. During the Phase I effort, Eagleware will define the synthesis environment and expand its direct filter synthesis package to include arbitrary distributed filters. Distributed filters are widely used in high frequency communications circuits. Successful design and implementation of these filters requires years of high frequency circuit design and layout experience. At present, a computer-aided synthesis tool for physical design of distributed filters with customized transfer functions is not available on the commercial market. Engineers designing communication and navigation systems, both wired and wireless, both defense and commercial, will be able to create better new systems faster. The synthesis environment automates the initial design of radios, radars, and other communication equipment. This automation draws on both the knowledge of past designers and the power of computers, resulting in designs that are superior to those done manually.

EDAPTIVE COMPUTING, INC. 2161 Blanton Dr Dayton, OH 45342
Phone: PI: Topic#:	(937) 433-0477 Dr. Praveen Chawla AF 01-226 Awarded: 13APR01
Title:	Requirements Modeling Technologies for Affordable C2 Systems
Abstract:	EDAptive Computing, Inc. (EDAptive) and Dr. Perry Alexander of the University of Kansas are pleased to present this proposal for a unique, commercially viable solution to the problem of automated analysis and intuitive requirements capture in Rosetta. Our Rapid & Effective Analysis and Capture TOol-suite for Rosetta (REACTOR) program applies results and technology from previous Rosetta development, our knowledge of operational analysis techniques, our expertise in Rosetta, and EDAptive's Rosetta capture tools to the problem of analysis and capture of Rosetta requirements. We propose an analysis toolset that provides four integrated capabilities: (i) an Interpreter that determines the values of individual Rosetta expressions; (ii) an Evaluator that uses the Interpreter to evaluate collections of Rosetta expressions and perform consistency checking; (iii) a Simulator that uses Rosetta timing domains and the Evaluator to evaluate Rosetta facets over input sequences; and (iv) an Analysis Framework to integrate multiple simulations to enable heterogeneous evaluation. Also, we will investigate integration of both EDAptive's Rosetta capture tool and COTS tools to form a rapid and effective Rosetta analysis and capture tool-suite. This proposal presents a focused approach to establish feasibility during Phase I, and prove the concept and prepare for technology transition during Phase II.Requirements modeling, as described in this proposal, will provide the most benefit to large and/or complex product developments and especially those that have multiple domains, disciplines, and interfaces; that have more than three people involved with the product development; or that are being developed by geographically dispersed development teams.

NEW SPAN OPTO-TECHNOLOGY, INC. 9370 SW 72nd Street, A-142 Miami, FL 33173
Phone: PI: Topic#:	(305) 321-5288 Mr. Ralph DeMasi AF 01-227 Awarded: 05JUN01
Title:	High Resolution Laser Warning Device with Directional Determination Capability
Abstract:	With the rapid development of laser weapons that are fast, accurate, and with high energy, many laser weapons have been incorporated in various military platforms. As a consequence, the safety concern of military personnel including aircrew demands for advanced laser warning devices that can help provide earlier warning and also provide detail enemy laser parameters for protection arrangement. Existing laser warning devices are not capable of providing all required laser parameters in a single device package. New Span Opto-Technology Inc. proposes herein a new laser warning device based on intelligent use of a high Finesse Fabry-Perot etalon. The new device with minimal device components can be rugged and compact packaged to satisfy military requirement on vibration insensitivity. It offers the capability of simultaneous coherence discrimination laser warning, laser wavelength determination, laser beam direction determination, and laser status (CW or pulsed) classification. Large field of view (over 100� full angle) and fast response are other important features. Phase I research will construct a laser warning device prototype for feasibility demonstration of the proposed concept. The device operation parameters will be evaluated. Phase II development will focus of achieving fast response using a specially designed integrated electronic evaluation chip.The successful development of the proposed laser warning device will be valuable to aircrew and other military applications by identifying enemy laser parameters in near real-time. Combining the required measurement features into a simple compact device is a significant advantage of the proposed concept. The development will also have significant impact to commercial applications including laboratory laser wavelength evaluator, territory surveillance position determination, aircraft automated landing through laser guiding, and laser based friend and foe identification.

PACIFIC ADVANCED TECHNOLOGY P.O. Box 359, 1000 Edison St Santa Ynez, CA 93460
Phone: PI: Topic#:	(805) 688-2088 Michele Hinnrichs AF 01-227 Selected for Award
Title:	Miniature Sensor for Aircrew Laser Warning
Abstract:	There is a considerable threat from laser weapons designed to blind and dazzle tactical aircrews. To protect the aircrew against such a threat, a light weight wide angle early warning laser sensor, that can detect both cw and pulsed lasers, as well as the direction of arrival would be a significant advantage in queuing a protection system. Pacific Advanced Technology (PAT) has three innovative approaches to solving this laser warning problem. These will be evaluated during Phase I, all use a single aperture for multi wave band coverage. One uses a speckle-gram coupled with optical signal processing, another uses diffractive optics and the third uses fiber Bragg gratings. Any can be packaged into a small lightwieght and low power sensor package. Our analysis has shown that the speckle-gram approach, for example, has the sensitivity to detect laser threats with a signal power density at the aperature of 10 microwatts. During the Phase I portion of this program, in coordination with the Air Force, each technology will be investigated in depth and the most approriate of the three will be developed into a protoype system during Phase II.A laser warning system has applications in the Dod and the commercial marketplace for law enforcement, as well as, laser safety applications. It is anticipated that a Phase III program to productize this hardware for commercical sale will follow the Phase II work.

ALPHATECH, INC. 50 Mall Road Burlington, MA 01803
Phone: PI: Topic#:	(781) 273-3388 Dr. Gil Ettinger AF 01-228 Selected for Award
Title:	Model-Based 3D LADAR ATR Development and Evaluation
Abstract:	We propose to characterize performance levels of a model-based 3D LADAR ATR system in order to understand the applicability of LADAR sensors to target exploitation in complex scenes. The MSTAR program has successfully demonstrated the applicability of model-based recognition to 2D SAR processing of targets in extended operating conditions (EOCs). We will thus extend that approach to 3D LADAR exploitation. 3D LADAR, by virtue of generating high resolution 3D geometric reconstructions of a scene, is a natural application for shape-oriented model-based reasoning. Our technical approach to 3D LADAR ATR consists of supporting single to multiple LADAR looks and is based on uncertainty modeling and hierarchical part-based surface alignment methods. The 3D recognition approach is well-suited for recognizing partially-occluded variably-configured targets in cluttered environments and is therefore an excellent candidate for ATR evaluation under EOCs. Our ATR evaluation methodology will also leverage the experience and tools developed under the MSTAR program, decomposing performance measures along the sensor, target, and environment operating dimensions. Our team is composed of the developers of MSTAR's model-based reasoning modules and the evaluators of the MSTAR system and is well-positioned to extend our SAR experience to LADAR performance characterization.The development of a structured evaluation process for 3D recognition technology has a wide range of commercial applications. The 3D surface matching technology we are proposing to leverage in this effort has been previously developed for medical image analysis applications. Developments made under this effort could therefore be utilized for medical applicationsdetecting and quantifying pathology in magnetic resonance (MR) and computed tomography (CT) imagery, where the pathology may exhibit a wide range of variable observables. In addition, industrial inspection over a variable range of controlled and uncontrolled illumination and part configuration conditions requires a well-defined process for 3D recognition performance evaluation, as will be developed under this program.

CHARLES RIVER ANALYTICS, INC. 725 Concord Avenue Cambridge, MA 02138
Phone: PI: Topic#:	(617) 491-3474 Mr. Magnus Snorrason AF 01-228 Awarded: 11APR01
Title:	Automatic Target Recognition Characterization using Causal Models
Abstract:	This proposal seeks to design a prototype evaluation framework for characterizing the difficulty of Automatic Target Recognition (ATR) Algorithms in Electro-Optical (EO) sensors. Our proposed framework provides the ability to express relationships between operating scenarios and algorithm performance. The ATR operating scenarios are parameterized by Extended Operating Conditions (EOCs), or conditions beyond those used during algorithm training and development. The result of this research will be a set of qualitative EOCs for four different sensor modalities: LADAR, PMMW, FLIR and CCD. Charles River Analytics has a strong background in developing algorithms for each of these sensors. In addition, multi-sensor datasets have already been collected and exist at our disposal for this project. A part of the prototype evaluation framework will allow the construction of causal models. These models will indicate which EOCs are most likely to cause problems for ATR algorithms. Finally, a set of experiments will be designed to assess the correctness of the developed models. Using ATR algorithms developed under previous contracts, baseline performance on existing datasets will be reported. These experiments will also be used to support the correctness of the evaluation framework and model. The empirical evaluation of Automatic Target Recognition algorithms has direct benefits to many military applications. Spin-off benefits (both government and commercial) of an evaluation framework include tools for automated test case generation, automated data collection criteria and measured performance evaluation. The potential also exists for the development of data mining applications for algorithm evaluation.

DATA FUSION CORP. 10190 Bannock Street, Suite 246 Northglenn, CO 80260
Phone: PI: Topic#:	(720) 872-2145 Dr. W. Kober AF 01-228 Awarded: 21APR01
Title:	Automatic Target Recognition Characterization for Electro-Optical Sensors
Abstract:	Data Fusion Corporation (DFC) proposes the development of a methodology and software toolbox for predicting the automatic target recognition (ATR) performance of an ATR system. DFC will create a quantitative theory of Extended Operational Conditions (EOCs) and incorporate these into information theory-based measures of ATR performance assessment.Evaluation of emerging sensors will be necessary in order to determine their readiness and applicability for commercial applications. In particular, use of HSI and 3-D laser data in automated manufacturing will require quantified performance estimates as a function of sensor quality, illumination, and manufacturing tolerances.

MICROCOATING TECHNOLOGIES, INC. 5315 Peachtree Industrial Blvd Chamblee, GA 30341
Phone: PI: Topic#:	(678) 287-3950 Mr. David Kiesling AF 01-230 Awarded: 07MAY01
Title:	S-BAND FERROELECTRIC PHASE SHIFTER
Abstract:	The advancements in thin-film manufacturing brought about by the development of the combustion chemical vapor deposition process has opened the door to a new class of microwave devices enabled by ferroelectric materials. One device in particular, a ferroelectric phase shifter, shows promise as a way of reinvigorating the development of phased array radar systems. Costly phase shifter designs, with prices around $25, have stymied interest in building large phased array radar antennas and have prevented the technology from being adopted by the private sector. A new monolithic phase shifter design is proposed that utilizes the ferroelectric material BaxSr1-xTiO3 (BST). The goal is to lower the cost of a phase shifter by 80%, to a price less than $5 and to reduce the size and weight by 50% over conventional designs. Such a device would reignite interest in phased array antennas for military applications and for commercial systems like smart antenna base stations for the wireless industry.Over one million elements and phase shifters have been manufactured for the needs of such programs as the Patriot, AEGIS, and Flap Lid radar antennas. The needs of even one radar program can drive high volume module production (e.g. 360 phase shifters and 34,769 elements were required for COBRA DANE radar systems). MMIC based components are currently utilized for these systems. For a 2 GHZ PCS band application, the current phase shifter costs are around $25/phase shifter which inhibit the commercial antenna vendors from adopting the active arrays. Consultations with industrial partners indicate that reducing phase shifter costs 80%, to $5, will make the technology attractive for large-scale use. Successful development of CCVD ferroelectric thin film technology for phase shifter applications will result in competitive pricing and will enable MCT and its industrial partners to capture a substantial share of this market over the next decade. Not only does CCVD have the potential for playing a pivotal role in defending/establishing the phase shifter industry in the U.S., the commercialization path that MCT will pursue with industry alliance partners will create a substantial number of highly-skilled and high-paying jobs.

V CORP. TECHNOLOGIES, INC. 7042 Nighthawk Court Carlsbad, CA 92009
Phone: PI: Topic#:	(760) 931-1011 Dr. Scott R. Velazquez AF 01-230 Awarded: 09MAY01
Title:	High-Speed, High-Resolution Advanced Filter Bank Analog and Digital Converter
Abstract:	This Small Business Innovation Research Phase I project demonstrates a breakthrough approach to very high-speed, high-resolution analog-to-digital conversion or digital-to-analog conversion which improves the speed of conversion by up to six times the state-of-the-art by using a parallel array of individual converters. The V-Corp Advanced Filter Bank Analog and Digital Converter (AFB ADC) architecture works because the filter bank signal processing significantly reduces the sensitivity to analog mismatches (e.g., phase distortion, clock skew, temperature drift) which prohibit existing parallel conversion methods (e.g., Time-Interleaving) from achieving high resolution. V-Corp has proven the technical efficacy of the concept by successfully building prototype analog-to-digital converter hardware with 12-bit resolution and 260 MHz sample rate (over twice as fast as state-of-the-art) and prototype digital-to-analog converter hardware with 14-bit resolution and 240 MHz sample rate (twice state-of-the-art). Very importantly, the AFB ADC architecture will never become obsolete and will always exceed the state-of-the-art because it can easily be upgraded as new, more powerful ADC products become available. The architecture is amenable to single-chip integration for compact, low-power applications. The AFB ADC technology enables an advanced all-digital shipboard array with multiple beams and a single aperture, steerable nulls to mitigate co-site interference and jammers, fast beam pointing and target acquisition, software reconfigurability, and affordability due to high levels of circuit integration. During Phase I, V-Corp will demonstrate the architecture with the very latest analog-to-digital or digital-to-analog converters, demonstrate an efficient auto-calibration section in hardware, and utilize proprietary linearity error compensation routines to improve the dynamic range of the system. A realtime hardware implementation of the digital signal processing in the AFB architecture will be implemented in a Phase I Option. During Phase II, a compact realtime implementation of the AFB ADC system (including the auto-calibration section) will be implemented and integrated in a target system (e.g., radar, GPS receiver, communications system according to the sponsor's requirements).The AFB ADC approach overcomes the critical A/D conversion bottleneck which limits performance of state-of-the-art radio frequency transceiver systems. Virtually any high-performance modern electronic system will benefit from the AFB ADC. Significant applications include enhancement of radar systems, wideband universal RF transceivers, specialized test equipment, and medical imaging systems.

ACULIGHT CORP. 11805 North Creek Parkway S., Suite 113 Bothell, WA 98011
Phone: PI: Topic#:	(425) 482-1100 Dr. Mark S. Bowers AF 01-231 Awarded: 19APR01
Title:	Compact Eyesafe Laser for High Resolution Range Imaging
Abstract:	The Air Force and other branches of the Armed Forces require laser transmitters for future laser rangefinders (LRF) that are capable of target ranging and improved spatial resolution for target identification. To meet the requirements of these future LRF's, Aculight Corporation proposes to develop a short pulse (<1 ns), eyesafe, high power, and high repetition rate laser source based on high power pumping of large-core erbium doped fiber amplifiers. This new approach uses a novel high brightness diode pump source to directly pump the fiber core permitting the use of shorter fibers, which increases the threshold of nonlinear effects resulting in efficient extraction of high pulse energy and high peak power pulses. Furthermore, this approach utilizes the best properties of diodes and fibers: high efficiency, compactness, reliabliabily, and reduced thermal issues, as well as providing direct eyesafe output. This concept, coupled with Aculight's novel packaging techniques, will result in a very efficient, compact, and robust laser source for future LRF. This work will develop a novel high power, high brightness semiconductor diode laser source that has commercial applications in the areas of pumps sources for fiber lasers and amplifiers and in industrial processing applications.

PROMETHEUS, INC. 103 Mansfield Street Sharon, MA 02067
Phone: PI: Topic#:	(401) 849-5389 Dr. William Moran AF 01-232 Selected for Award
Title:	Multi-Mission Waveform Design
Abstract:	We shall implement multiple complementary waveforms by frequency separation with an adaptive waveform selective probability data association filter (PDAF) tracking system. The system will track potential targets and maintain a probability estimate of each track. As a result, detection and moving target indication (MTI) may be accommodated by hypothesis testing on the statistical information in range-doppler space available from the tracker. This will provide functions which are close to optimal on a sequential basis while optimally selecting the next waveform for each pulse repetition interval (PRI) to minimise error covariance. The waveforms will be taken from a library of complementary sets of waveforms selected for their ambiguity performance in range and doppler. Techniques for construction of a wide variety of such waveforms have been established by Prometheus. Preliminary results show that there are clear advantages in the use of such waveforms with frequency and/or time separation over currently implemented ones. Phase I work will focus on establishment of a library of waveforms with diverse ambiguity properties, and on implementation of the waveform selective multiple target tracker with MTI and detection capability. A simulation package will demonstrate capability in a variety of clutter and noise scenarios. The ultimate objective of a waveform selective radar system employing multiple virtual radars will provide back-end multi-function capability to existing and future radar systems with waveform agility. It will have high-level resolution and detection capacity and thereby enhance surveillance performance of military radar systems.

STIEFVATER CONSULTANTS 10002 Hillside terrace Marcy, NY 13403
Phone: PI: Topic#:	(315) 334-4365 Dr. Richard Schneible AF 01-232 Selected for Award
Title:	Multi-Mission Waveform Design
Abstract:	The goal of this project is to develop a waveform design approach that can optimize the waveform suite for a multiple mission airborne or space-based radar syste. Future surveillance concepts envision platforms with multiple radars (at different frequencies) on the same platform. Each of the radars will be addressing aspects of various missions (AMTI, GMTI, SAR). The optimization of a multi-radar, multi-mission waveform suite requires a detailed analysis of the performance of waveforms for each mission. Closed-form analytical approaches to waveform optimization will be inadequate for this complex problem. Evolutionary computational approaches (modeled on biological evolution) will be employed to meet this need. This approach maintains a population (i.e., waveforms) that evolve according to the rules of mutation and selection. The good news for the waveform optimization process is that the selection can be accomplished on a mission-by-mission basis.Multiple-mission waveform selection has applicability in any radar system (military, civilian government, commercial) that attempts to reduce costs by performing more than one mission with the same RF hardware. Another major market for multuple-application waveforms is the commercial wireless communications sector. This internationally growing market deals with waveform conflict problems very similar to those addressed in the proposed radar application. Wireless commuication could provide a more cost-effective capability if waveforms could be developed that would improve the ability to simultaneously pass multiple messages of multiple types to multiple locations.

HYPERTECH SYSTEMS LLC 4 Dickens Court Irvine, CA 92612
Phone: PI: Topic#:	(949) 477-1019 Dr. David Slater AF 01-237 Awarded: 27JUN01
Title:	Hyperspectral Target Signature and Background Clutter Modeling in Tree Regions
Abstract:	In this project we will develop innovative techniques for modeling hyperspectral target signatures and background clutter in tree regions. We will focus on the modeling of deep hide targets that are obscured between 50% and 100% by tree canopies. The measured sensor spectrum for a target under a tree depends on the target's geometric and physical properties, the three-dimensional tree canopy architecture, and the optical properties of the leaves and soil. We will use DIRSIG and PROSPECT to construct spectral subspaces to examine target/background contrast and target signature variability for targets under trees over ranges of tree and leaf parameters as well as over the environmental conditions. The analysis will allow us to gain insight into the fundamental physical processes that govern signatures for targets under trees as well as to establish the range of conditions over which targets under trees can be recognized reliably using hyperspectral images. We will also develop physics-based spectral/spatial models for background clutter in tree regions. These models can be used for automated tree region segmentation and for the estimation of tree and leaf parameters from image data. The accuracy of the new modeling techniques will be evaluated by comparing the generated models with hyperspectral image data and by analyzing the performance of algorithms that utilize the new models. The new algorithms can be used in systems for surveillance, reconnaissance, and targeting applications. Related algorithms have important commercial applications in areas such as biomedicine, mining, and agricultural and environmental monitoring.

PHYSICAL OPTICS CORP. 20600 Gramercy Place, Bldg. 100 Torrance, CA 90501
Phone: PI: Topic#:	(310) 530-7892 Dr. Paul Shnitser AF 01-237 Awarded: 20JUN01
Title:	Portable Hyperspectral Camcorder for Ground-Truth Data Collection
Abstract:	Physical Optics Corporation (POC) proposes development of a portable hand-held hyperspectral camcorder to be used for collecting ground truth spectral and polarization signatures as well as geometrical information of potential targets and backgrounds. The proposed device offers flexibility in the selection of spectral resolution and in the number of used spectral intervals and their positions. It will be capable of recording high quality spectral images for different states of light polarization. Therefore, a full Stokes vector for each pixel in spectral images will be obtained. Color coordinates for each pixel in the image will also be measured with high accuracy. The proposed hyperspectral camcorder will reduce the time required for collection of bidirectional spectral reflection (or emission) functions for the objects of interest, therefore stimulating comparison of the real data with numerous computer models. It can also be used on airborne platforms for tactical applications, such as real-time detection and identification of low-visibility targets hidden in cluttered background or light-scattering media. In Phase I, POC will demonstrate the proof of concept by modifying a commercially available camcorder. In Phase II, POC will optimize the Phase I prototype for hand-held operation. Preliminary Phase III commercialization activities will begin in Phase I. The development of the proposed device will stimulate the use of hyperspectral imaging for detection and identification of hidden targets. It will provide the necessary experimental data for development of computer algorithms for simulation of the sensor's performance. It will reduce the time required for collection of spectral signatures and will also provide a variety of additional information that will stimulate development of target detection algorithms and innovative sensors. The resulting technology will have a broad range of commercial applications, such as environmental monitoring and medical imaging.

POLATIN CORP. 57 Janet Terrace New Hartford, NY 13413
Phone: PI: Topic#:	(315) 731-9433 Dr. Paul F. Polatin AF 01-237 Awarded: 07MAY01
Title:	Realistic Simulation of Low-Frequency Radar Terrain Clutter
Abstract:	The research described in this proposal is intended to provide the basis for the development of advanced models for prediction and analysis of low-frequency radar signatures of ground targets in terrain clutter. The specific purpose of the proposed work is to formulate an accurate and computationally efficient approach, including prototype computer models, for simulating radar scattering between 30 MHz and 1 GHz by targets that are electromagnetically coupled to ground cover. Using the formulation and physics-based models that are the intended product of this work, it should be possible to accurately predict monostatic and bistatic radar signatures of targets concealed in, or obscured by, ground clutter.The ultimate objective of this proposed work is the development of a comprehensive set of computational modules that would be integrated into existing commercial radar signature prediction software. The overall commercialization plan also includes integration of the advanced clutter modeling capability into a suite of software tools currently being developed for use in RF/wireless site layout and remote sensing applications.

COLLIER RESEARCH CORP. 45 Diamond Hill Rd., 54-1746146 Hampton, VA 23666
Phone: PI: Topic#:	(757) 825-0000 Mr. Craig Collier AF 01-239 Awarded: 29MAR01
Title:	Virtual Test Certification of Aerospace Structures by Analysis
Abstract:	Certification tests for aircraft vehicle structures are necessary to ensure the load carrying capability and performance of each component and/or assembly. However, hardware testing is costly and delays the design cycle. Substantial cost and time savings are possible by replacing a certification test with a virtual test by analysis. The objective of this proposed effort is to identify an Air Force certification test in the structural airframe verification process that can be targeted for phased replacement by selected analysis methods and associated software tools. For these tools, research will be performed into their limits of applicability and enhancements made to include risk/confidence assessments or to expand the limits of applicability. An airframe component approach will be used that requires many structural analysis technologies be considered. Lockheed Martin Aerospace (Fort Worth, TX and Marietta, GA) will assist with determining criteria for certification and provide candidate test data from the F16, F22, and from a planned full-scale structural component of a redesigned C-130 cargo floor. A certification test will be chosen that considers the potential cost benefit (business case), and is applicable to unmanned air vehicles, space access vehicles, future strike fighters, and/or sustainment of military aircraft.A broad range of analytical certification methods would be developed and implemented into the commercial airframe structural analysis product called HyperSizerr. The primary application of the method would be for military aircraft. The method may also be used either directly or with minor modifications by aerospace companies building components for the NASA led $4.5 billion Reusable Launch Vehicle program, for commercial transports, for general aviation aircraft, and other transportation industries such as rail car and shipping.

R-TEC 28441 Highridge Rd., Suite 530 Rolling Hills Est, CA 90274
Phone: PI: Topic#:	(310) 378-9236 Dr. Mohan M. Ratwani AF 01-240 Awarded: 10APR01
Title:	Development of Validated Crack Measurement System for Vibrating Structures
Abstract:	In-service failures are known to occur in aircraft structures due to vibratory loads. Structural design and test engineers are constantly striving to develop techniques to predict life of components, prevent the initiation and propagation of damage, and enhance the service life of structural components. Recent advances in crack growth measurement techniques such as Visual Crack Measurement System (VCMS), and repairing metallic structures with composites has provided opportunities to: 1) Develop a unified system for measuring crack growth in complex structures under random vibratory loads, 2) Prevent acoustic fatigue failures from initiating in the remainder life of an aircraft, and 3) Retard the growth of the cracks that have already initiated. The proposed program will: 1) Develop an integrated VCMS for structures subjected to vibratory loads, 2) Evaluate the capabilities of present analyses and AFGROW software to predict crack initiation and growth in structures subjected to vibratory loads, 3) Evalute the application of current AFGROW bonded repair analytical techniques to predict crack growth in structures with bonded repairs and subjected to vibratory loads, 4) Verify the application of the VCMS with test data, and 5) Modify, if needed, present life prediction techniques for application to vibratory structures.The proposed program will develop and demonstrate the application of validated Visual Crack Measurement System which can be used by aerospace, pipeline, automotive, and other industries to carry out reliable acoustic fatigue tests. This will significantly cut down on test time and cost. The anlaytical techniques evaluated in the proposed program along with the methodology developed will provide efficient tools that can be used by aerospace and other industries to predict life of structures without heavy emphasis on testing. In addition, the developed methodology will provide means to design composite patches to enhance the service life of in-service structures subjected to vibraoary loads. This will significantly reduce maintenance cost of aircraft structures.

APPLIED MATERIAL TECHNOLOGIES, INC. 2302 S. Fairview Street Santa Ana, CA 92704
Phone: PI: Topic#:	(714) 545-8825 Mr. William De La Torre AF 01-242 Awarded: 12APR01
Title:	Novel Diamond Substrates Isothermally Cooled by Evaporative Spray
Abstract:	Inserting new high power sensors and electronics on the E-8 aircraft will require highly effective cooling. Diamond substrates cooled by evaporative spray techniques can satisfy requirements for both extraordinary cooling effectiveness and tailorability to advanced radar systems. M. S. Sehmbey et al have demonstrated that evaporative spray cooled diamond surfaces can maintain components, with high heat fluxes, within a narrow isothermal temperature range. In this study, an isothermal temperature range of 120�C-150�C was maintained despite heat flux increases of 700 W/cm2 to a maximum (for the test conditions) of 1150W/cm2. These results established that combining diamond surfaces with evaporative spray cooling could generate the highly effective cooling needed by future airborne radar. Two developments have created the potential for producing such a system: (1) novel diamond substrates fabricated from network polymers and (2) turn-key evaporative spray cooling systems currently being evaluated in DoD systems. A key feature, in both of these developments, is their tailorability to system configurations and cooling requirements thus creating the opportunity to produce highly effective modular and scalable cooling systems. AMT, Inc. will lead a team to design diamond/evaporative spray cooling systems tailored for the E-8 aircraft and other airborne radomes and electronics. Potential dual-use commercial applications include cooling of high power electronic switching systems, high power land based communications systems, satellites, and high-end computers and electronics.

SYTRONICS, INC. 4433 Dayton-Xenia Road, Building 1 Dayton, OH 45432
Phone: PI: Topic#:	(937) 431-6106 Mr. Timothy Joe Choate AF 01-244 Awarded: 29MAR01
Title:	Enroute Mission Planning Rehearsal (EMPAR)
Abstract:	SYTRONICS proposes to solve the problem of integrating real-time sensor and other remote data, effective battlespace planning and threat laydowns, and three-dimensional (3-D) pilot's perspective visualization by integrating four COTS/GOTS technologies: (1) PFPS--the USAF's Pre-Flight Planning System; (2) FalconView--the USAF's graphical mission visualiza-tion/laydown tool; (3) EMPRS--a Ball Aerospace product which provides connectivity to all information sources through all necessary communication channel's and supports enroute team training; and (4) LandForm--a 3-D mission modeling application which transforms DTED data to 3-D in real-time, overlays mission information, and provides the pilot's perspective for mis-sion fly-throughs. The Phase I Objectives are to (1) define requirements to specify perform-ance and assessment measures for the required enroute mission planning and rehearsal capabil-ity; (2) develop a top-level architecture design to the extent necessary to perform the feasibility assessments; (3) assess feasibility through experimentation and analysis by developing an initial prototype and conducting experimental testing, analyses, and demonstrations; and (4) assess commercial product potential to ascertain the commercial potential. The Phase I Results will be the requirements--experimentally-proven and demonstrated feasibility and the top-level design and the product assessment--to form a sound foundation for Phase II and commercialization.Military users of Enroute Mission Planning Rehearsal will benefit from improved training and mission rehearsal with live information, conducted enroute and amongst different units being deployed (team training). Commercial applications include portable, distributed training sys-tems for commercial or civilian pilots. Also, commercial users will be able to rehearse their roles in business, commerce, and industrial activities to improve organization efficiency and effectiveness.

SYSTEMS & ELECTRONICS, INC. 190 Gordon Street Elk Grove Village, IL 60007
Phone: PI: Topic#:	(847) 228-0985 Mr. Joseph F. Braun AF 01-245 Awarded: 28APR01
Title:	Effect of Parameter Accuracy and Variance on Structural Life Prediction and Life-cycle Costs
Abstract:	Systems & Electronics, Inc (SEI) proposes a program of research study for quantifying the effect of parameter accuracy and variance on structural life prediction and life-cycle cost of airframe structural details. In particular, parameters related to the structural configuration, material types, flaw geometry, component tolerances and loading regime will be studied and the significance of variations in these parameters affecting estimated life, cost of inspection and repair will be quantified. The main tasks of SEI's proposal include: (1) conduct a comprehensive review of current life protection models; (2) select two types of structural details and conduct an analysis of parameter accuracy and variation for these details; (3) integrate aircraft life-cycle cost and aircraft availability models with life prediction analysis model; (4)recommend modification in design and life prediction methods; (5)conducting a trade-off study to determine the benefit-cost associated with future research areas in life estimation methods; (6)prepare directions for research in Phase II and commercialization plan for Phase III; and (7)prepare a final report. The proposed research has a great deal of military and commercial applications in the areas related to fatigue damage and life expectancy evalution of aircraft components.The results from this research is expected to provide a more refined method of crack growth fatigue life prediction for aircraft components. Immediate application of the research will be for military and commercial aircraft. The findings from this research will link the variation and accuracy in design parameters to cost and aircraft availability. This is expected to reduce aircraft operations and service cost.

VISUAL COMPUTING SYSTEMS CORP. P.O. Box 250, 9540 Highway 150 Greenville, IN 47124
Phone: PI: Topic#:	(812) 949-7924 Dr. Patrick M. Kelecy AF 01-246 Awarded: 05APR01
Title:	Power Dense, Electro-Mechanical Planar Actuator for Flight Vehicle Systems
Abstract:	Air Force and NASA studies have shown that up to 20% can be saved in launch vehicle operation and support costs by replacing hydraulic and pneumatic systems with electrically driven systems. However, current electro-mechanical actuation technology lacks the power density to be a viable replacement. The objective of this effort is to demonstrate the feasibility of a lightweight, high torque, electro-mechanical actuation (EMA) system attractive for service in reusable launch vehicle applications. The proposed system is based on a planar, permanent magnet machine structure that utilizes a novel armature design. This system is expected to provide 5 to 8 times greater power density than current, state-of-the-art EMA technology.If this project succeeds, a small, power dense EMA technology will exist that is able to compete with hydrualic and pnuematic actuation technology. Commercial aviation and aerospace are likely markets for this technology, as similar cost saving should be realized. High power, low weight actuators and motors are also of great interest to industrial manufacturers, particularly those now using hydraulic or pneumatic servo systems.

COMBUSTION RESEARCH & FLOW TECHNOLOGY 174 North Main Street, P.O. Box 1150 Dublin, PA 18917
Phone: PI: Topic#:	(215) 249-9780 Mr. Neeraj Sinha AF 01-247 Awarded: 01MAY01
Title:	Active Flow Control of Turbulence for Airborne Directed Energy Weapons
Abstract:	The application of airborne and ground-based high power lasers as Directed Energy (DE) weapons is under consideration for the Joint Strike Fighter (JSF). Depending upon the integration selected for the laser, varied forms of turbulence is encountered along the beam propagation path, e.g. turbulent boundary layer, free shear layer, or wake. Flowfield turbulence creates a highly non-uniform and time-varying, three-dimensional, fluctuating density field, and causes a propagating optical wavefront to incur phase delays and become aberrated. Aero-optical wavefront errors produce beam spreading in high-energy laser weapon beams, which drastically reduces target irradiance and lethality for laser weapons and impairs laser-guided bomb accuracy. Optical degradation by turbulent flow, and compensation by adaptive optics, is compounded by the broad spectrum of turbulence frequencies, which can exceed 10 kHz for typical fighter flowfields. The time-dependent interaction of an optical wave front with a turbulent flow is poorly understood. The Phase I program will provide fundamental characterization of this interaction through small-scale beam propagation experiments, complimentary LES modeling & analytical description of beam degradation. This paves the path for implementation of high-frequency, active flow control of turbulence around the DE weapon with the goal of reducing the demand upon the adaptive compensation system.The proposed SBIR research will lead to an actuator design and integration concept, which can be directly transitioned to the JSF program. Beyond DE weapons, the flow control technology for reduction of optical degradation by turbulence is of great relevance for reduction of bore-sight-error (BSE) for a tracking system or elimination of blur in the case of an imaging system. From the perspective of flow control, the high frequency actuator is relevant to the current research in aircraft exhaust noise reduction and aircraft plume infra-red (IR) signature reduction.

COMPOSITEX 7117 Boulder Way Frisco, TX 75034
Phone: PI: Topic#:	(972) 712-0241 Mr. Daniel J. Moser AF 01-247 Awarded: 18APR01
Title:	Stealth UAV with Integrated Propulsion, Control, and Powered Lift
Abstract:	Compositex proposes to develop and demonstrate a revolutionary powered lift, propulsion, and control system for a small, high-performance, stealth UAV platform. The proposed aircraft system is a unique configuration that utilizes upper surface blowing (USB) to propel and control the craft, while also enabling it to attain a very high (>6) maximum lift coefficients, resulting in very low minimum airspeeds. The system concept is very simple, allowing dramatic weight reductions and improved reliability, with excellent prospects for all-weather operation, improved ground crew safety, and noise reduction on small UAV platforms. The proposed Phase 1 effort includes basic research, the development of design/analysis tools, and the design, fabrication, and aerodynamic testing of a proof-of-concept prototype UAV. The prototype test article includes fully powered USB devices and wind tunnel-style instrumentation. The degree of control effectiveness and propulsive efficiency will be characterized experimentally on the full-scale test article. At the conclusion of the Phase I effort, the results from a 3-D potential flow CFD analysis will be compared to experimental test data.A small, lightweight, all-weather UAV platform, invisible to radar, and able to loiter at extremely low minimum airspeeds would be a very useful tool in close-in surveillance missions. It is also low cost, simple, reliable, and relatively quiet when operating. The technology is adaptable to several other aircraft applications.

COMBUSTION RESEARCH & FLOW TECHNOLOGY 174 North Main Street, P.O. Box 1150 Dublin, PA 18917
Phone: PI: Topic#:	(215) 249-9780 Mr. Neeraj Sinha AF 01-248 Awarded: 20APR01
Title:	Adaptive Mesh Controller for Computational Analysis
Abstract:	Numerical simulation of store separation from weapons bays or wing pylons is made difficult by the need to move the computational mesh and provide adequate resolution of flow structures that are changing with time. Recent advances in unstructured grid methods have demonstrated that an adaptive grid, which is coarsened and/or refined to accommodate the motion of the store, is a viable approach for performing realistic separation scenarios. The proposed program focuses on the extension of an existing unstructured mesh adaptation code, CRISP, to include the elements necessary for computing turbulent store separation on mixed element meshes. A node movement procedure, currently operational for tetrahedral grids, will be extended to treat viscous, hybrid element meshes. Mesh quality sensor criterion will determine where and how the mesh is to be modified, using existing refinement and coarsening techniques. Solution adaptation will be demonstrated for a realistic aircraft configuration. These investigations will demonstrate the potential effectiveness of the CRISP code in performing store separation calculations using adaptive grid techniques. The resulting mesh adaptation tool-kit will be invaluable in performing assessment of weapons dispense systems.The proposed research is directly relevant to the assessment of weapons bay and weapons dispense designs for future and current aircraft. The research supports the development of novel computational methods for simulating flowfields with moving bodies and boundaries. Adaptive, moving grids find ready application in the simulation of heart valves, internal combustion engines, fluid/structural interactions, and other areas where the need to move the computational mesh is a major concern.

SIMMETRIX, INC. 1223 Peoples Ave. Troy, NY 12180
Phone: PI: Topic#:	(518) 276-2729 Dr. Mark W. Beall AF 01-248 Awarded: 25APR01
Title:	Toolkit for Automatic Mesh Generation and Adaptation to Control Discretization Errors and Geometry Changes
Abstract:	This project will develop a general purpose automatic meshing toolkit appropriate for implementing automated, adaptive analysis systems. The new toolkit will build off of existing capabilities that include isotropic surface and volume meshing direct from CAD data, boundary layer meshing for CFD applications, and adaptive mesh procedures. New capabilities to be added include anisotropic surface and volume meshing and remeshing, mesh modification techniques to introduce anisotropy, a generalized error indication framework with specific techniques for compressible flow problems and solution transfer techniques. The combination of the existing and new capabilities will result in a comprehensive toolkit that will be applicable to many different problem domains.The software to be developed will be used by companies that develop Computer Aided Engineering (CAE) software for a number of different domains. Having these techniques available as an easy to use toolkit will enable these companies to more quickly and cheaply develop advanced software for physics-based modeling and simulation. The techniques to be developed have obvious applications in the Computational Fluid Dynamics area, however they will also be useful in virtually any type of simulation. Simmetrix will market and license this software to companies developing CAE software.

APPLIED SYSTEMS INTELLIGENCE, INC. 10882 Crabapple Road Roswell, GA 30075
Phone: PI: Topic#:	(770) 518-4228 Mr. Carl Lizza AF 01-249 Awarded: 30MAR01
Title:	Affordable Control/Trajectory Management Systems for Unmanned Air or Space Vehicles
Abstract:	There is a major need for unmanned vehicles that act autonomously from humans, thereby reducing both the amount of supervision necessary and the cost associated with their operation. In order to accomplish this task, autonomous vehicles must have the ability to make decisions, assess their health and environment, dynamically re-plan, and control their movements in a dynamic and unpredictable environment. Our goal is to design an affordable control technique that 1) reduces the necessary human interaction, 2) responds to both anticipated and unanticipated events, 3) allows easy verification and validation of vehicle behavior, and 4) is as effective as an equivalent manned vehicle. In order to meet these objectives, ASI plans to implement an associate decision aiding system that uses knowledge about the environment and context in which it is operating, as well as the potential purposes of the system and its operators. It can act in concert with one or more humans to perform complex tasks, and is designed explicitly to work interactively and cooperatively with human counterparts, unlike either conventional automation or autonomous software agents.Demand for unmanned vehicle systems continues to grow in every major world region. The United States, as well as many foreign countries have UAVs, all of which could take advantage of our system. Military systems can also utilize components of our technology, by implementing data fusion and situation assessment capabilities. Data fusion can be part of a collaborative intelligence network. Situation assessment technology can be used in a variety of domains, including battlefield management, flight operations, and mission planning. Although military procurement will continue to represent the majority of industry revenues, intense competition in military markets will force some companies to gear new marketing efforts toward civil and commercial customers. As such, ASI plans to broaden the market for associate systems by pursuing commercial opportunities for our technology and products, particularly in air traffic management, general aviation and agricultural vehicles. Specifically, from this SBIR, we expect to apply the concepts of controlling unmanned vehicles to agricultural domains, from combines to professional turf maintenance vehicles. We also expect to utilize advanced flight navigation concepts in unmanned Department of Transportation traffic monitoring and police surveillance vehicles. In addition to using our technology in unmanned systems, we can also extract components of the total system for use in situation assessment displays and data fusion applications. Our situation assessment module would be particularly successful in an advanced cockpit setting, like that proposed by the FAA's Advanced General Aviation Transport Experiments (AGATE) program. This program is designed, in part, to develop affordable, low-cost, intuitive cockpit displays that provide situation, weather, and traffic awareness to support Free Flight. Data fusion can also be used in public safety and emergency management venues, where information gathering and synthesis is necessary.

ORBITAL RESEARCH, INC. 673G, Alpha Drive Cleveland, OH 44143
Phone: PI: Topic#:	(440) 449-5785 Mr. Ravi Vaidyanathan AF 01-249 Awarded: 09APR01
Title:	Collective Intelligence and Effective User-Command Interface for UAV Swarm Missions
Abstract:	The effective coordination of large groups, or "swarms" of Uninhabited Air Vehicles (UAVs) working collaboratively demands the development of control architectures that emerge collective intelligence among groups of autonomous individuals. Nature, through evolution and natural selection, has optimized this behavior. Insect societies, in particular, demonstrate an organized "swarm intelligence" beyond the capacity of any individual within their troupe to understand. Although possession of similar capabilities would optimize the performance of uniform UAV swarms, this cannot be achieved without autonomous control strategies dictating successful interactions between large numbers of these entities. Further benefit could be achieved if effective tool sets could be developed allowing a single user to control an entire swarm during battle. Orbital research, leveraging past successes in control of autonomous vehicle swarms, proposes the development of group behavior algorithms to direct missions for UAV collectives, and simplistic user interfaces for operator control. Phase I will: 1) Develop algorithms capable of directing swarm intelligence for UAV groups, 2) Develop software simulations to optimize group interactions among UAV units, and 3) Develop of tactical user interfaces allowing a single user command over combined UAV swarms.In addition to filling an available niche in autonomous flight control, this system is to anticipated have very lucrative markets in both military and civilian arenas. Potential commercial opportunities encompass virtually any situation where multi-unit coordination is necessary such as control and simulation of microsatellite swarms, conventional and micro-robots, intelligent highway systems (ITS), and manufacturing lines where automated units must interact without human supervision.

ALPHATECH, INC. 50 Mall Road Burlington, MA 01803
Phone: PI: Topic#:	(781) 273-3388 Dr. Jerry M. Wohletz, David A. C AF 01-250 Awarded: 13APR01
Title:	Distributed, Cooperative Control for a Team of Autonomous, Tactical UAVs
Abstract:	Cooperative, autonomous control is required to realize the full potential of autonomous assets in a tactical operational setting. For a tactical battlespace, there are many levels of applications requiring cooperative control. This proposal addresses the mission control level where the control task is to coordinate multiple heterogeneous distributed assets to achieve the desired global effect through the application of local force. When viewed as a centralized control problem under uncertainty, Stochastic Dynamic Programming (SDP) provides the optimal control strategy for this stochastic problem; however, this solution approach is not computationally feasible for most problems, and requires excessive centralization of information and computation. In this proposal, we present innovative distributed control strategies that extend previous ALPHATECH Approximate Dynamic Programming (ADP) successes to cooperative control of tactical UAVs. The PHASE I work will extend these ADP strategies to the domain of cooperative mission control of UAVs, and evaluate alternative distributed approaches for control coordination. The most successful approaches will be developed in detail in the PHASE II work. The proposed technology would enable autonomous heterogeneous distributed UAVs to cooperatively search, detect, identify, engage, and destroy enemy targets in a highly dynamic, uncertain environment, with limited human input. This concept of operations would tailor the application of force, and thus achieve massed affects without relying on massed forces and sequential operations; as a result, a significant improvement in operational efficiency can be realized. In the commercial sector, this technology is directly transferable to many applications involving autonomous systems, such as deep-sea exploration and salvage, hazardous material handling, flexible manufacturing systems and space-based assembly and repair.

COI CERAMICS, INC. (formerly Engineered Ceramics), 9617 Distribution San Diego, CA 92121
Phone: PI: Topic#:	(858) 621-7466 Dr. Peter J. Widmann AF 01-251 Awarded: 13APR01
Title:	Aerospace Structures Technology
Abstract:	Oxide-based CMC materials, new ceramic adhesives, and design concepts developed for thermal protection systems and engine hot parts will be combined to create an advanced nozzle liner for augmented and unaugmented exhaust. Manufacturability and cost savings will be demonstrated for a bonded load-bearing structure. Provision for active cooling and the inherently low short/mid wave IR emissivity and dielectric constant of oxide-oxide CMCs will be exploited to make the structure Low Observables compatible. Conceptual design and thermal and dynamic structural analyses will be performed in Phase I and a subcomponent will be tested at NASA GRC. Phase 2 will culminate in test of a large-scale component in the AFRL thermo-acoustic facility.Our approach to exhaust washed structures offers significant advantages over metal components and conventional CMCs. The oxide-based CMCs require only a single infiltration step saving processing costs. Our advanced ceramic adhesives will permit use of bonded structures, which will lower fabrication costs and life cycle costs through better maintainability and repairability. Compatibility with LO requirements will lead to increased survivability of future military aircraft.

IPITEK 2330 Faraday Avenue Carlsbad, CA 92008
Phone: PI: Topic#:	(760) 930-2220 Dr. David Schaafsma AF 01-251 Awarded: 17APR01
Title:	Multi-Sensor Intelligent Systems for Structural Health Monitoring
Abstract:	We propose to develop neural net processing to interpret data from multi-sensor fiberoptic systems and diagnose structural responses on legacy aircraft such as the C-141. Our team of IPITEK, Lockheed Martin Aeronautics Company (LMAero), and the Georgia Institute of Technology will develop complete systems using multiplexed fiberoptic sensors, smart self-diagnosing instrumentation, advanced data processing such as pattern recognition, multi-sensor correlation, trending, on-line dynamic finite element analysis and neural networks. Using aircraft network capability developed by IPT and LMAero, these systems can be integrated into an aircraft-wide structural monitoring system which can exchange data with other health monitoring and flight systems as well as provide data to maintenance personnel, thereby reducing the need for periodic inspection and maintenance and lowering the cost of keeping aging fleets aloft.The need for health monitoring in aging aircraft is by no means restricted to the military, with the average age of much of the commercial fleet now well past the design lifetime of 20 years. These systems can also be applied to civil structures (such as the aging US bridge system), industrial automation, and advanced robotics and aerospace vehicles.

ZONA TECHNOLOGY, INC. 7430 E. Stetson Drive, Suite 205 Scottsdale, AZ 85251
Phone: PI: Topic#:	(480) 945-9988 Dr. Danny D. Liu AF 01-252 Awarded: 30MAR01
Title:	Integrated Hypersonic Aerothermoelastic Methodology for TAV/TPS Structural Design and Optimization
Abstract:	Current Trans-Atmospheric Vehicle (TAV) design requires Aerothermoelastic analysis to ascertain the TAV/TPS (thermal protection system) structural integrity in extreme hypersonic environments. A comprehensive aerothermoelastic software system requires a high-fidelity hypersonic unsteady aerodynamics method that is panel-FEM compatible to a structural-FEM design/optimization software such as NASTRAN or ASTROS. ZONA7U is a unified hypersonic/supersonic panel method that satisfies all requirements and is proven computationally efficient with comparable accuracy to CFD/Euler solutions. The ZONA team (ZONA Technology and TechnoSoft) will adopt ZONA7U as the unsteady/steady aerodynamic basis of the proposed Aerothermoelastic software system for TAV/TPS design/optimization. ZONA7U will be integrated with other required discipline/software in SHVD (Supersonic Hypersonic Vehicle Design), currently under development by TechnoSoft and Lockheed-Martin, including Aeroheating (SHABP/BLAH), Trajectory Analysis (POST), TPS