Award Data

Silicon Q-PICs provide a miniature, stable, and scalable platform for developing future light-based quantum technologies, including sensors, secure communications, and information processors. This is due in large part to leveraging existing semiconductor manufacturing capabilities and the dense integration that the high index contrast of silicon can achieve. In order to fully implement quantum arc ...

The objective of this STTR is to develop a highly autonomous hull grooming system that can be operated easily and cost effectively with minimal supervision. The focus of the Phase 1 effort was to design and characterize the navigation system that can provide the required accurate on-hull navigation. The focus of the Phase 2 Base effort is to demonstrate closed loop autonomous control for relative ...

The objective of this proposed effort is to develop a highly autonomous hull-grooming system that can be operated easily and cost-effectively with minimal supervision. This system will meet the rigorous standards of current manned-grooming operations using a rotating brush tool and will ensure complete coverage of the groomed area by providing on-hull positioning accuracy of 0.15m. We will develop ...

For this Phase 1 Small Business Technology Transfer (STTR) project, Blackmore Sensors and Analytics and university partner Montana State University will investigate the use of coherent frequency modulated continuous wave (FMCW) ladar/lidar and digital holography techniques for improved performance of active imaging through fog. Coherent range, Doppler, and polarization selective digital holography ...

This STTR seeks to develop a high-throughput, low-cost enabling technology for the manufacturing of electronic systems-on-film. It posits a novel concept of introducing percolation networks into semiconducting “inks” to increase by at least an order of magnitude the very low carrier mobilities (

This proposal addresses the need for an innovative and affordable material system that mitigates low frequency acoustic radiation through the hull induced by airborne noise in shipboard compartments containing Electronic Modular Enclosures. The proposed low frequency acoustic mitigation treatment is based on multiply-tuned, micro-sized absorbers embedded into a viscoelastic polymer matrix with a ...

This Phase II proposal addresses the need for an innovative, affordable spray-on material system that mitigates low frequency acoustic radiation through a ship hull induced by airborne noise in shipboard compartments containing various electro-mechanical systems. The Phase I project objectives were fully achieved and the results exceeded the U.S. Navy project requirements. The acoustic mitigation ...