Abstract: An addressing scheme for use with current-driven emissive displays requires that an N-row by M-column array of pixels be divided into K segments of N/K rows each. One transistor-controlled current driver is provided for each column of pixels within a segment, and all of a segment's current drivers are connected to a respective gate address line. The array is addressed by dividing a frame time into N/K “sub-frame” times. During the first sub-frame time, the current drivers of each segment are turned on in sequence, and the first row of each segment addressed. The remaining rows are addressed in this manner during subsequent sub-frame times. The segmenting and addressing scheme reduces the duty ratio required to drive the array by a factor of K, and reduces the number of transistors required to drive the array by a factor of N/K, when compared with comparably-sized passive matrix and active matrix displays, respectively.

Abstract: An ultra-low noise, high gain interface pixel amplifier is provided with capability for single-photon readout of known photodetectors at high electrical bandwidths for diverse spectral bandpass from the x-ray to long IR bands. The detector charge modulates a source follower whose output is double sampled to remove correlated noise by a compact stage that also provides optimum level shift for subsequent amplification of the full signal excursion. The level-shifted signal finally drives a compact amplifier that generates a robust end-to-end transimpedance. Single-photon readout of photodetectors at high electrical bandwidths in small pixel areas is thereby facilitated.

Abstract: A wireless network of communicating devices, preferably including sensors, uses a distributed method of topology learning to organize multiple hop, relayed communication among the devices and with users. The method of topology learning identifies interference neighbors and communication neighbors for each device, preferably using ranging between devices and distributed calculation to limit the number of devices involved in each step of the topology learning method, thereby conserving energy and bandwidth. The identification of interference neighbors and communication neighbors for each device in the network facilitates scheduling of communications in any of a variety of multiple access protocols.

Abstract: A reversible electrochemical mirror (REM) includes a first electrode and a second electrode, one of which is substantially transparent to at least a portion of the spectrum of electromagnetic radiation. An essentially nonaqueous electrolytic solution, disposed between the first and second electrodes, contains ions of an electrodepositable metal having a molar concentration of more than 0.5 M. The electrolytic solution also contains halide and/or pseudohalide anions having a total molar concentration ratio of at least 2:1 relative to the concentration of the electrodepositable metal cations. A negative electrical potential applied to the first electrode causes deposited metal to be dissolved from the second electrode into the electrolytic solution and to be electrodeposited from the solution onto the first electrode to form a mirror deposit, thereby affecting the reflectivity of the REM device for electromagnetic radiation.