Abstract: A gallium arsenide device converts an ECL voltage signal to a gallium arsenide voltage signal. The device has a pair of depletion transistors for transforming the ECL voltage signal and a predetermined reference voltage into corresponding signal and reference currents to provide pull-up. A pair of enhancement transistors are connected to the pair of depletion transistor for outputting the gallium arsenide voltage signal which is representative of the ECL voltage signal. Positive feedback means for increasing the gain of the pair of enhancement transistors is provided and is connected to the pair of enhancement transistors. The predetermined reference voltage may be derived from a set voltage source or may be derived from a logical one level in the ECL circuit so as to provide temperature tracking for the gallium arsenide circuit. At least a third depletion transistor is connected to a third enhancement transistor.

Abstract: An oxide fuse, and method of forming same, formed by a thin layer of oxide dielectric between a lower electrode substrate and an upper electrode. A fuse-programming bias of approximately 15V causes Fowler-Nordheim tunneling at low temperature to damage the dielectric layer, and shorts the upper and lower electrodes together. The oxide layer is advantageously formed simultaneously with the gate oxide layer in an EEPROM.

Abstract: A threshold receiver circuit consists of a reference subcircuit and one or more signal input subcircuits. The reference subcircuit derives a mirror voltage by regulating a reference current flowing through an external reference resistor. The mirror voltage is distributed to each of the signal input subcircuits. Within each signal input subcircuit a signal transistor has its gate connected to the mirror voltage and its drain connected to a common input node, thereby causing a signal current to flow into the common input node which is proportional to the reference current. The signal current also flows through an external signal input resistor which is connected to the input node, and into the external input signal source. The input node voltage is thus equal to the input signal source voltage plus the voltage-drop across the signal input resistor. This input node voltage is compared to an internal reference voltage by a comparator which is also connected to the common input node.

Abstract: A fiber optic interferometric hydrophone is based on the change in optic path length of optic fibers bonded to both sides of a bending beam which acts as an acoustically sensitive diaphragm.The bending beam is segmented into an even number of segments, acoustic windows are arranged such that opposite sides of the beam see the acoustic field in adjacent segments, and the optic fibers cross from one side of the beam to the other to maintain the phase of strain signal for the two fibers, one on each side, along the full length of the bending beam. The fringe sensitivity of the interferometer is multiplied by two since both interferometer legs are strained by the acoustic field, and of opposite sign, and further multiplied by the number of segments compared to a single simple beam bender of the dimensions of one segment.