Abstract: Radar imaging for medical diagnosis addresses the need for non-ionizing and low-cost alternatives to conventional medical diagnosis methods, such as mammography x-ray techniques, which expose patients to ionizing radiation for cancer detection. An ultra wide band (UWB) sensor can produce very fine beams at the V- or W-bands using beam forming techniques developed specifically for wafer scale antenna arrays. The high bandwidth radio waves can penetrate tissue and resolve tissue anomalies with high-resolution. Pseudo-random coding creates a signal that allows the correlating receiver to extract very low energy reflected signals from background noise providing coding gain. An integrated panel of sensor antenna arrays enables rapid scanning of the subject area, such as breast tissue, to detect anomalies by eliminating the need for mechanical scanning (e.g.

Abstract: Methods and systems are disclosed for scalable antenna arrays that may be built up using pluggable tiles that have low distortion, flat band high gain, and structured to channelize the signals into narrow bands that may be 40 MHz or even smaller bandwidth apart. Antenna array tiles may employ traveling wave tube (TWT) components and wafer scale arrays. H-topology, equal length, feed networks connect the signals to antenna elements. The fractal-like, recursively repeating at different size scales, structure for the H-tree feed networks, implemented using pluggable tiles, facilitates the scalability of the high gain waveguide antenna array. System integration across the 75-115 GHz spectral band implements scalable aperture architecture with emphasis on addressing considerations of the TX power requirement, feed network, channelizing signals at different frequency bands using specially designed diplexers and combiners, cooling, component placement, and isolation.

Abstract: An ultra-wideband (UWB) radar imaging system is carried by a mobile platform—such as an aircraft—the UWB radar imaging system including multiple UWB radar sensors; the UWB radar sensors transmitting a high resolution radar signal using an array of power amplifiers and corresponding polarizing antenna arrays to form spatial power combining and beam forming from each UWB radar sensor; and receiving reflections using an array of low noise amplifiers and corresponding antenna arrays to form spatial power combining from the reflections at each. UWB radar sensor; processing the radar sensor data from the UWB radar sensors by an imaging processor for detecting a ballistic projectile; and providing trajectory information of a detected ballistic projectile on a display. Trajectory modeling enables fusing the radar sensor data with optical or thermal imaging data and the trajectory information to display a probable source location of the detected ballistic projectile.

Abstract: An energy harvesting and storage system includes an array of piezoelectric electrodes, in which the piezoelectric electrodes generate electrical energy from mechanical displacements of the piezoelectric electrodes; and an array of capacitor electrodes disposed in proximity to the piezoelectric electrodes, in which the array of capacitor electrodes stores a portion of the energy generated by the piezoelectric electrodes. An energy system includes a substrate including an array of micro-post electrodes connected to a cathode layer of the substrate; an isolation material covering the array of micro-post electrodes; and an anode layer including electrodes filling the remaining region between the isolation material-covered micro-post electrodes, in which the anode layer, electrodes, isolation material, micro-post electrodes, and substrate are monolithically coupled.