Award Data

This Sequential Phase II effort will demonstrate the micro-loop oscillating heat pipe heat spreader technology (m-Loop-OHP-HS) for solid state power amplifiers in a real-world spacecraft structure to advance its technology readiness level for near-term insertion into programs of record. Additionally, the m-Loop-OHP-HS technology will be prototyped in novel materials and form factors to create mult ...

The computational framework designed to meet the technical requirements of Simulation Governance with the goal of enabling reliable predictions of damage accumulation caused by cyclic loading in metallic airframe components that have small initial flaws, will be validated at the component level. The predictive performance of the model to determine the remaining fatigue life of mechanical component ...

To reduce size, weight, power and cost (SWaP-c), military platforms have been evolving towards a more integrated design approach that efficiently utilizes all available space. In fact, to accommodate limited space constraints many commercial off-the-shelf (COTS) systems will need to be replaced by custom designed and fabricated components. For radiofrequency (RF) electronic systems, this will requ ...

The goal of the proposed Phase II SBIR project is to advance the research, development, and evaluation of a novel plasma actuator technology referred to as SLIPPS (Smart Longitudinal Instability Prevention via Plasma Surface) for reducing aerodynamic drag on air vehicles. More specifically, the Phase II project will demonstrate net power drag reduction on an airfoil section similar to that used on ...

This proposed Phase II sequential effort will build upon the Phase I and original Phase II programs by: 1) Supporting AFRL's ongoing flight experiment of Oscillating Heat Pipe (OHP) chip carriers to evaluate their compatibility with and performance in a space environment; 2) Expanding the OHP operating limits and steady-state performance models to further improve the predictability (and perceived ...

Under the proposed effort, PSI will continue to develop a novel pmmW imaging technology developed under a prior Navy program to realize dense form factor arrays. This technology is based on an optical upconverted distributed aperture technology that can make large effective apertures in low SWaP form factors thereby maximizing achievable resolution. This sensor technology has already reached TRL 6 ...

Electrical systems are being designed with ever increasing power densities, particularly future radar and electronic warfare systems built with Gallium Nitride on Silicon Carbide Monolithic Integrated Circuits (GaN MMICs). Today’s GaN MMICs use solid metal, low-coefficient of thermal expansion heat spreaders (e.g., Copper-Tungsten). But solid-state heat spreaders cannot meet the size, weight, po ...

Aircraft designed for today’s Navy are being pressed into service beyond their design life resulting in increase in failure rates of parts that were not expected to fail. The Phase II base project will be based on Phase I and Phase I Option work to develop a full restoration system that can be used to restore various aircraft components. The components in a damaged aircraft component will be use ...

When imaging over long distances, atmospheric turbulence between the camera and subject degrades the collected data limiting the effective resolution, regardless of the quality of the optic and sensor used. This reduction in image quality can have serious impacts on the ability to carry out missions by reducing situational awareness and preventing target identification. EM Photonics has been worki ...

Under the proposed effort, PSI will leverage a novel pmmW imaging technology developed under a prior Navy program to realize the low size, weight, and power sensors required for UAV implementation. This technology is based on an optical upconverted distributed aperture technology that can make large effective apertures in low SWaP form factors thereby maximizing achievable resolution. This sensor ...