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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.
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SBC: RADIABEAM TECHNOLOGIES, LLC Topic: N16AT010
The 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 goal of this Phase II effort is to develop and validate Electron Beam Melting (EBM) additive manufacturing (AM) technology for the production of vacuum electronic devices meeting t ...STTR Phase II 2018 Department of DefenseNavy
SBC: Carbonics, Inc. Topic: A18BT004
Carbonics, Inc. is the only small business entity that is razor-focused on developing and commercializing wafers-scale carbon nanotube (CNT) based RF products for mmWave communications that can outperform incumbent semiconductor high frequency technologies (GaAs & RF-CMOS). Our STTR Phase I accomplishments exceeded all expectations, setting a new world record for CNT FET RF technology (fT > 100 GH ...STTR Phase II 2020 Department of DefenseArmy
SBC: Cognionics, Inc. Topic: A16AT014
This STTR project will develop a wearable sensor suite for accurate assessment of circadian and sleep rhythms with the goal to identify abnormalities in PTSD patients and enable personalized therapy to help restore their normal functional and quality of life. Phase I has already demonstrated proof-of-principle hardware. The primary Phase II objective is to successfully carry out a human subjects s ...STTR Phase II 2018 Department of DefenseArmy
Evidence-Based, User-Centered Design Process for Improvement of the Utility of the Surface Electronic Warfare Display SuitSBC: PACIFIC SCIENCE & ENGINEERING GROUP, INC. Topic: N11AT031
In Naval, surface electronic warfare (EW), visual displays form critical bridges between warfighters and the complex operational radio-frequency (RF) spectrum they must monitor and interpret. Surface electronic warfare operators and supervisors must monitor and interact with multiple, stove-piped display systems in order to perform their work. Further, the visual displays they employ are not desig ...STTR Phase II 2018 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: Technology Service Corporation Topic: MDA06T003
In Phase I, TSC and the University of Arizona developed a new generalized Space-Time Adaptive Processing (Generalized STAP) algorithm that discriminates among classes of scatterers that move on generalized space-time paths. The new formalism was applied to three-dimensional (3D) imaging of objects in the missile threat complex while suppressing radar dipole clutter by means of adaptive complex we ...STTR Phase II 2007 Department of DefenseMissile Defense Agency
SBC: BRAINLIKE, INC. Topic: N05T025
This proposal offers a System for improving decisive inferences based on Air Deployable Active Receive (ADAR) sonar, in a form that is suitable for deployment on ADAR sonobuoys. Anticipated near-term improvements include better target recognition and reduced operator fatigue, brought about through improved ping data filtering on ADAR aircraft. Anticipated long-term improvements include increased ...STTR Phase II 2007 Department of DefenseNavy
SBC: VECTOR ATOMIC INC Topic: A18BT014
Vector Atomic and Stanford University will develop precision, ultra-low noise laser control electronics with low cost, size, weight, and power (C-SWaP). The electronics will be designed to broadly support the various laser types of used for quantum technology, which span 369-1550 nm. The C-SWaP and system architecture will support scaling of quantum systems to higher laser counts. The design will ...STTR Phase II 2020 Department of DefenseArmy
SBC: SYNVITROBIO, INC. Topic: A18BT016
There is a need to develop affordable and specific biosensors to defend against current and future biological threats. Biological methods of detection have been evolved by nature to detect molecules at the micro-scale with flexible specificity and with downstream effectors. Advances in cell-free technology allow for deployment of biosensors on pH-strip-type paper, an affordable, robust, disposable ...STTR Phase II 2020 Department of DefenseArmy
Innovative Technologies Supporting Affordable Increases in Power, Efficiency, and Bandwidth for Ballistic Missile Defense System (BMDS) X-Band RadarsSBC: Group4 Labs, LLC Topic: MDA06T012
This Phase-II STTR proposal proposes the use of a new class of diamond-seeded solid-state material system for the manufacture of virtually all packaged intense heat-generating solid-state electronics in X-band and Ballistic Missile Defense radar components and systems. In this proposal wherein much preliminary (also MDA-funded) work has been demonstrated hitherto by the authors, Gallium Nitride-on ...STTR Phase II 2007 Department of DefenseMissile Defense Agency