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SBC: Stottler Henke Associates, Inc. Topic: ST16C003
We propose to investigate, in collaboration with the Massachusetts General Hospital Voice Center and Altec, Inc., the application of surface electromyography (sEMG) to assessing cognitive workload, strain, and overload. Specifically, sEMG sensors placed on the face and neck will detect emotional/motor responses to workload strain. The proposed effort will build on the substantial sEMG experience o ...STTR Phase I 2017 Department of DefenseDefense Advanced Research Projects Agency
A Multiphysics Framework Utilizing Nonlinear Material Models for Predicting Impact of Structural Profile Disruption on High-Velocity Air VehiclesSBC: ATA ENGINEERING, INC. Topic: AF17AT025
The aerothermal environment for hypersonic flight vehicles is severe and can generate extremely high material temperatures. These high-temperature environments can cause intense localized heating, which may result in local pockets and/or structural instabilities, especially at vehicle leading-edge regions, and may lead to disruptions that affect vehicle performance. The aerothermal environment may ...STTR Phase I 2017 Department of DefenseAir Force
SBC: POLARONYX INC Topic: DHP15B002
Based on our success in developing the world first commercial high energy femtosecond fiber laser system and our leading proprietary technology development in ultrashort pulsed fiber laser material processing, PolarOnyx proposes, for the first time, a compact high energy fiber laser based smart wound healing tool to meet with the requirement of this DHP solicitation. It includes a high energy fs f ...STTR Phase I 2016 Department of DefenseDefense Health Agency
SBC: AKELA INC Topic: A16AT004
Laboratory 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
SBC: ATTOLLO ENGINEERING, LLC Topic: AF16AT22
Current scene projection hardware is challenged to simultaneously meet the requirements for high peak temperature (> 2000K), high resolution (2Kx2K), response time < 4 ms, cryogenic and temporally uniform photon flux. MEMS, Resistor arrays, liquid cr...STTR Phase I 2016 Department of DefenseAir Force
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
Simultaneous Time-Resolved Gas and Particle Flow Measurements in a Multiphase Blast Using Particle Imaging Velocimetry and Novel Phase Separation TechniquesSBC: METROLASER, INCORPORATED Topic: AF17AT020
An experimental method is proposed to enable time-resolved measurements of both gas and particle velocities in explosions containing particles for munitions research. The approach involves novel processing methods for two-dimensional images that allow discrimination of the image content based on particle size. This allows an image containing a poly-dispersed distribution of particles to be decompo ...STTR Phase I 2017 Department of DefenseAir Force
SBC: UTOPIACOMPRESSION,CORPORATION Topic: DHP16C005
The goal of this STTR effort is to design a portable, multimodal, non-contact imaging system for burn depth diagnosis and tracking of wound healing. UC and Vanderbilt University will build upon our previous efforts demonstrated via porcine model studies to combine results from structural B-mode optical coherence tomography (OCT) images and functional data (pulse speckle imaging- PSI) to classify d ...STTR Phase I 2017 Department of DefenseDefense Health Agency
SBC: Arete Associates Topic: A17AT020
Historically, the monitoring and detection of biological threats has been carried out via the deployment of high sensitivity / high complexity monitoring nodes to insure high probability of detection and low false alarm rate. Unfortunately, this detection strategy has inherent limits with respect to coverage and response due to its high deployment/support costs, mandating a new approach to environ ...STTR Phase I 2017 Department of DefenseArmy
Fully Metallic Self-Fragmenting Structural Reactive Materials Using Composites and Alloys Comprised of Aluminum, Lithium, and MagnesiumSBC: Adranos Energetics LLC Topic: DTRA16A002
While aluminum casing materials provide some enhanced performance and thermal loading to explosive ordinance, their overall effectiveness is highly limited by incomplete combustion and long residence times. In order to reduce these problems, the casing material must be designed to facilitate rapid fragmentation through either specialized casing geometries or greatly refined initial particle sizes. ...STTR Phase I 2016 Department of DefenseDefense Threat Reduction Agency