Award Data

Few-cycle mid-infrared lasers are highly demanded for a variety of practical applications. NP Photonics and University of Arizona propose to develop a wavelength tunable and power-scalable optical parametric laser system at 8-12 micron capable of producing collimated few-cycle pulses with pulse energy>100 microJoule. In this phase I program, we will design the whole laser system and do a feasibil ...

We propose a wearable, dual-use neurotechnology device. The Personal Brainwave Headband, driven by tablet or smartphone, is designed for noninvasive closed-loop acoustic stimulation, to permit improved circadian regulation. It will measure brain electrical activity from scalp overlying four key sectors of cortex, perform high-resolution spectral analysis of the signals, and use software algorith ...

A collaboration between research engineers at Solid State Scientific Corporation and the University of MassachusettsBoston proposes the exploration of a new class of superconducting traveling wave parametric amplifier (TWPA) that exploits the large nonlinear inductance of a unique quantum device known as a superinductor. The nonlinear properties of the superinductor provide high gain of weak sign ...

Autonomous or teleoperated navigation of unmanned ground vehicles (UGVs) is difficult even in benign environments due to challenges associated with perception, decision making, and human-machine interaction, among others. In environments with rough, sloped, slippery, and/or deformable terrain, the difficulty of the navigation problem increases dramatically. In this effort, Quantum Signal, LLC, Un ...

This project address the fabrication of solar blind detectors from the MgZnO material system. Both MBE and MOCVD material growth techniques will be used for deposition of the required material layers. Simulation software we be used to aid in the design of the photodetector structure. Devices will be fabricated from the grown structures and their electrical and optical characteristics determined.

In this STTR proposal, we propose a novel computational technology for analyzing millimeter wave and sub-millimeter wave scattering from complex and electromagnetically extended objects and environments. The core of our formalism lies in a technique for rapidly calculating and coherently adding fields produced by different scatterer constituents, ranging from conducting, flat surfaces to penetrabl ...