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Award Data
The Award database is continually updated throughout the year. As a result, data for FY24 is not expected to be complete until March, 2025.
Download all SBIR.gov award data either with award abstracts (290MB)
or without award abstracts (65MB).
A data dictionary and additional information is located on the Data Resource Page. Files are refreshed monthly.
The SBIR.gov award data files now contain the required fields to calculate award timeliness for individual awards or for an agency or branch. Additional information on calculating award timeliness is available on the Data Resource Page.
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Acoustically/Vibrationally Enhanced High Frequency Electromagnetic Detector for Buried Landmines
SBC: AKELA INC Topic: A16AT004Laboratory investigations have suggested that acoustically or vibrationally inducing motion in buried targets can aid in improving target detectability through a characteristic response related to differential target motion. This gain is realized by adding an additional degree of freedom, modulation due to motion in the GPR return signal, to use as a discriminating feature. The AKELA team is propo ...
STTR Phase I 2016 Department of DefenseArmy -
Active Control of a Scramjet Engine
SBC: Innoveering, LLC Topic: AF15AT19In this effort, Innoveering will integrate and test a closed-loop active control system for scramjet isolator shock system positioning. The approach is to control the fuel flow to the engine to position the shock train leading edge at a specified location in the isolator. The control system includes three basic elements: a shock position sensing system based, a fast response fuel valve that adjust ...
STTR Phase II 2016 Department of DefenseAir Force -
Active Control of Scramjet Isolator Shocks (ACSIS)
SBC: Innoveering, LLC Topic: AF15AT19ABSTRACT: Active control of the shock system in a scramjet engine isolator opens possibilities for enhanced engine performance and reduced engine weight by eliminating excess isolator design margin. A successful system will allow for maximum performance from a given engine configuration and will deliver range and efficiency that exceeds those possible using passive unstart control. Our approach is ...
STTR Phase I 2015 Department of DefenseAir Force -
Adaptive Cyber-secure Cross-layer Communications-Classification System (AC4S): Cyber Superiority for Air Force Combatant Commanders Using Cyber-domain
SBC: ANDRO COMPUTATIONAL SOLUTIONS LLC Topic: AF08BT06ABSTRACT: In this effort selected SBIR technologies will be matured and merged to establish the Adaptive Cyber-secure Cross-layer Communications-Classification System (AC4S) for enhancing the throughput, spectral efficiency, speed, reliability and security performance of software defined radio (SDR) communication networks. One of the core technologies in the AC4S architecture is the Cyber Superior ...
STTR Phase II 2016 Department of DefenseAir Force -
Adaptive Cyber-secure Cross-layer Communications-Classification System (AC4S): Dynamic Cross-layer Routing Using Cognitive Spectrum Allocation (AXL-RO
SBC: ANDRO COMPUTATIONAL SOLUTIONS LLC Topic: AF10BT09ABSTRACT: In this effort selected SBIR technologies will be matured and merged to establish the Adaptive Cyber-secure Cross-layer Communications-Classification System (AC4S) for enhancing the throughput, spectral efficiency, speed, reliability and security performance of software defined radio (SDR) communication networks. One of the core technologies that forms the basis of AC4S is the AXL-ROSA s ...
STTR Phase II 2016 Department of DefenseAir Force -
Additive Manufacturing for Microwave Vacuum Electron Device Cost Reduction
SBC: RADIABEAM TECHNOLOGIES, LLC Topic: N16AT010The Department of the Navy has a need for the development of an additive manufacturing (AM) process for key vacuum electronic device components to meet on-demand, flexible, and affordable manufacturing requirements. The developed manufacturing method has a potential to reduce cost of vacuum electronics by as much as 70% as well as simplify and hence expedite production process of these devices by ...
STTR Phase I 2016 Department of DefenseNavy -
Advanced Printed Circuit Board Design Methods for Compact Optical Transceiver
SBC: ATTOLLO ENGINEERING, LLC Topic: A15AT001As the warfighter is increasingly using more highly integrated instruments, e.g. a laser rangefinder (LRF) combined with a laser designator and an imager, the need to decrease the size of these components becomes more important. Compact small munition applications of rangefinders particularly place an emphasis on size of the optical front end. In order to make the transceiver more compact, speci ...
STTR Phase I 2015 Department of DefenseArmy -
Advanced Silicon Diode Switch for HPRF Systems
SBC: RADIATION DETECTION TECHNOLOGIES, INC. Topic: N15AT023Silicon-based photoconductive switch technology, despite its widespread industrial use, has not reached its limit in repetition-rate nor recovery-time. While traditional Si-PCSS systems have demonstrated poor recovery time (tens to hundreds of microseconds), new understanding in absolute photo-carrier generation and the resultant reduced sweepout time, provides one means to get beyond this seeming ...
STTR Phase I 2015 Department of DefenseNavy -
A High-Level Operator Abstraction for GPU Graph Analytics
SBC: Royal Caliber Topic: ST13B004We are proposing a new software framework for analyzing very large graphs using massively parallel processors (GPUs). This framework will be commercialized on a cloud platform that gives users immediate access to highly advanced big-data analytics through a user-friendly web interface, as well as an HTTP API for easy integration. The platform can be deployed on a private cloud if desired. The sy ...
STTR Phase II 2015 Department of DefenseDefense Advanced Research Projects Agency -
Aircraft Carrier-based Precision Ship-Relative Navigation Guidance for Aircraft Landing under Emissions Control Conditions
SBC: SA PHOTONICS, LLC Topic: N15AT014This proposal describes an all optical fixed wing landing system for a aircraft carrier capable of flying an aircraft all the way to landing in a RF denied environment. The precision, reliability and accuracy of this system will allow control the aircraft without the help from the pilot all the way to touch down. It will work seamlessly with UAVs and manned aircraft that have been retrofitted with ...
STTR Phase I 2015 Department of DefenseNavy