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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.

  1. A Compact Solid Acid Electrolyte Fuel Cell Generator

    SBC: SUPERPROTONIC, INC.            Topic: A08T010

    This project addresses the Army's needs for a compact power source. The system design is based on state-of-the-art high CO tolerant solid acid fuel cells (SAFCs) operating at 250 degrees C and a thermally matched methanol reformer creating a 20 Wnet lightweight, rugged, efficient unit capable of running for 72 hours with an energy density of about 1 kWh/kg.

    STTR Phase I 2008 Department of DefenseArmy
  2. Acoustically/Vibrationally Enhanced High Frequency Electromagnetic Detector for Buried Landmines

    SBC: White River Technologies Inc            Topic: A16AT004

    White River Technologies, Inc. (WRT) presents this proposal, "Acoustically/Vibrationally Enhanced High Frequency Electromagnetic Detector for Buried Landmines".The primary goal of the proposed effort is to develop a prototype vibrationally-enhanced detection system capable of landmine and IED detection and discrimination with performance greater than conventional GPR sensors.The main sensing compo ...

    STTR Phase II 2017 Department of DefenseArmy
  3. Acoustic Mitigation System For Horizontal, Planar Surfaces Onboard Naval Ships

    SBC: NEVA ASSOC.            Topic: N08T014

    Typical acoustic materials rely on embedded continuous mass layer to attenuate low frequency sound. Energy from low frequency sound is not effectively mitigated with these materials unless a substantial amount of mass is added. Thus, standard materials for low frequency noise control tend to be heavy, expensive and difficult to install. A new technology is being developed that utilizes optimized ...

    STTR Phase I 2008 Department of DefenseNavy
  4. Adaptive and Smart Materials for Advanced Manufacturing Methods

    SBC: NEXTGEN AERONAUTICS, INC.            Topic: AF17AT018

    Additive manufacturing (AM) technologies covering a broad range of technologies and processes have been under continuous and accelerating development since the 80s. While there are still fundamental hurdles such as low production rates and small sizes, AM holds tremendous promise in terms of revolutionizing manufacturing. Recent trends include direct-printing and incorporating sensors and electr ...

    STTR Phase I 2017 Department of DefenseAir Force
  5. Adaptive Hierarchical Multiple Models to Control Dynamic Systems

    SBC: SCIENTIFIC SYSTEMS CO INC            Topic: AF07T012

    Modern control theory offers mathematically rigorous and powerful solutions to many dynamic systems. Its limitations are that the classes of dynamic systems covered by the theory are limited to linear systems or certain well-structured nonlinear systems, and the adaptation of the controllers are often slow if the controller parameters are far away from their desired values. On the other hand, the ...

    STTR Phase I 2008 Department of DefenseAir Force
  6. Adaptive Management and Mitigation of Uncertainty in Fusion (AMMUF)

    SBC: CHARLES RIVER ANALYTICS, INC.            Topic: MDA13T001

    In our Adaptive Management and Mitigation of Uncertainty in Fusion (AMMUF) project, we will model the entire multi-sensor fusion process as a probabilistic model and reason about the different design and algorithmic decisions that can be made by system engineers. This fusion model will use standard fusion system representations and ideas from statistical relational learning field to create flexibl ...

    STTR Phase II 2015 Department of DefenseMissile Defense Agency
  7. Adaptive Optics controlled nonlinear propagation of USLP

    SBC: ADVANCED SYSTEMS & TECHNOLOGIES INC            Topic: N17AT024

    Filamentation of ultra-short laser pulse propagation in non-linear media offers significant potentials allowing to address numerous problems in military and commercial sectors. However, practical implementation of this requires an ability to control the USLP at its propagation through inhomogeneous media, like turbulent atmosphere. On the basis of our approach for combating turbulence effects on p ...

    STTR Phase I 2017 Department of DefenseNavy
  8. Adaptive Optics for Nonlinear Atmospheric Propagation of Laser Pulses

    SBC: TOYON RESEARCH CORPORATION            Topic: N17AT024

    Ultra-short pulse lasers have advantages over continuous-wave lasers for directed-energy applications due to the high peak powers that can be reached. Directed-energy weapons are profoundly limited by the aberrations caused by atmospheric turbulence and current adaptive optics can correct for these aberrations only when the propagation medium is reciprocal. Unfortunately, nonlinear effects in the ...

    STTR Phase I 2017 Department of DefenseNavy
  9. Adaptive TIL System for Long Range Laser Beam Projection with Enhanced Resolution

    SBC: METROLASER, INCORPORATED            Topic: A07T019

    Efficient laser beam delivery on a remote target remains a key problem for practical implementation of tactical laser systems. Since the conventional target-in-the-loop (TIL) concept is generally not effective in such operational environments, new solutions are needed. MetroLaser has developed an innovative approach for effective compensation of laser beam aberrations in TIL systems. It is based o ...

    STTR Phase II 2008 Department of DefenseArmy
  10. Additive Manufactured Smart Structures with Discrete Embedded Sensors

    SBC: TRITON SYSTEMS, INC.            Topic: A17AT024

    The purpose of this proposal is to additively manufacture (AM) smart structures with embedded electronics such as sensors, accelerometers, antennas, etc. The goal of these smart structures will be to enhance the effectiveness and survivability of the Armys ground systems. The use of additive manufacturing smart structures provides flexibility in the materials used and the functionality of the elec ...

    STTR Phase I 2017 Department of DefenseArmy
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