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The Award database is continually updated throughout the year. As a result, data for FY23 is not expected to be complete until September, 2024.
Download all SBIR.gov award data either with award abstracts (290MB)
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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.
SBC: DEUMBRA, INC. Topic: N05T019
It is computationally infeasible to implement a complete Level 2/3-fusion solution that has detailed knowledge of all parts of an area of interest all the time. A staged approach is needed where the first stage implements a real time peripheral vision sensor analysis to identify asymmetric threats. The second stage implements a “foveal vision” sensor analysis that identifies, links and valid ...STTR Phase II 2006 Department of DefenseNavy
A Novel Single Sideband Suppressed-Carrier (SSB-SC) Technique for High Dynamic Range Analog ApplicationsSBC: IPITEK, Inc. Topic: N05T008
Photonic links and networks offer numerous advantages to analog RF systems, and enable advanced performance in Naval aircraft analog RF systems: spurious-free dynamic range (SFDR) exceeding 125 dB/Hz^2/3 with instantaneous bandwidth up to and exceeding 1GHz for operational frequencies from 0.1 to 20 GHz. IPITEK proposes a novel single sideband suppressed-carrier (SSB-SC) technique that offers a ...STTR Phase II 2006 Department of DefenseNavy
A Multiscale Modeling and Simulation Framework for Predicting After-Burning Effects from Non-Ideal ExplosivesSBC: REACTION ENGINEERING INTERNATIONAL Topic: N10AT002
The objective of the proposed Phase II STTR effort is to develop a validated computational tool to predict the afterburning of non-ideal munitions containing metal and hydrocarbon fuels. The activities outlined devise a well-coordinated collaboration among researchers from Reaction Engineering International (REI) and the State University of New York at Buffalo (UB). The activities proposed will bu ...STTR Phase II 2015 Department of DefenseNavy
SBC: SIGNATURE RESEARCH, INC. Topic: NGA18A001
The multidisciplinary area of GEOINT is changing and becoming more complex. A major driver of innovation in GEOINT collection and processing is artificial intelligence (AI). AI is being leveraged to help accomplish spatial analysis, change detection, and image or video triage tasks where filtering objects of interest from large volumes of data is critical. NGA is confronting the changing GEOINT l ...STTR Phase II 2020 Department of DefenseNational Geospatial-Intelligence Agency
SBC: POLATOMIC, INC. Topic: N04T002
This SBIR Phase II proposal describes the development of a breadboard Advanced Optically-driven Spin Precession Magnetometer (AOSPM), an ultra high-sensitivity scalar laser magnetometer for airborne ASW. The AOSPM is an innovative high-sensitivity instrument capable of measuring scalar DC and ELF magnetic fields with a sensitivity better than 10.0 fT/root-Hz. Since the high sensitivity AOSPM is a ...STTR Phase II 2006 Department of DefenseNavy
SBC: CALNETIX Topic: N04T013
During the NAVY STTR Phase II Calnetix will further develop its concept of advanced flywheel system proposed in Phase I and will demonstrate the validity of the underlying principles through building and testing a system prototype. This prototype will be a fully functional system capable of supporting up to 2MW of pulse power with the ability of producing 500kW (30 seconds) loads in high-duty-cyc ...STTR Phase II 2006 Department of DefenseNavy
SBC: Texas Research Institute, Austin, Inc. Topic: N18AT008
Texas Research Austin (TRI-Austin) will continue to partner with the University of Texas, Austin, to use additive manufacturing for fabricating and optimizing the lithium ion and electroactive metal electrode systems for which the team established proof of concept in the Phase I base period. The Aerosol Deposition Method (ADM) is a broadly applicable additive manufacturing technology that has been ...STTR Phase II 2019 Department of DefenseNavy
SBC: STORAGENERGY TECHNOLOGIES INC Topic: N18AT008
The objective of the efforts being proposed is to develop high energy density and power density batteries with long cycle life by high-speed additive manufacturing technologies.STTR Phase II 2019 Department of DefenseNavy
SBC: CHIRP CORP. Topic: N04T007
The problem is to improve airborne maritime radar detection of small moving targets in clutter, where the clutter varies with time, range, azimuth, sea state, grazing angle, wind speed, and the look direction of the radar relative to the wind direction. A new version of space-time adaptive processing (STAP) is applied to the problem. The new technique provides improved covariance estimation for ...STTR Phase II 2006 Department of DefenseNavy