Abstract: The present invention is directed to a photoconductive switch module. The photoconductive switch module comprises a first substrate having light-emitting elements, and a second substrate having photoconductive switch elements, whose number is equal to that of the light-emitting elements. The light-emitting elements face the photoconductive switch elements, so that the photoconductive switch elements are turned on/off in accordance with lighting/extinction of the light-emitting elements. The photoconductive switch module further comprises a third substrate arranged between the first substrate and the second substrate. The third substrate has through holes, whose number is equal to that of the light-emitting elements. Each through hole is positioned between a light-emitting element and a photoconductive switch element facing each other. Drive light emitted from each light-emitting element travels to the photoconductive switch element via the through hole.

Abstract: A substrate, a method for producing a substrate, and a switch incorporating a substrate are disclosed. In one embodiment, the substrate has a first layer, a first electrode deposited on the first layer, and a second layer mated to the first layer. The second layer defines a duct leading from the first electrode to a surface of the second layer opposite the first electrode. A liquid electrode fills at least a portion of the duct.

Abstract: The switch device includes first and second cavities, a passage extending between the cavities, a conductive liquid located in the passage and movable therein, a conductive path that includes the conductive liquid, an actuating liquid enclosed in each of the first and second cavities and covering the inner surfaces thereof and an actuating gas enclosed in each of the first and second cavities and existing as a bubble therein. At least one of the cavities includes a constriction element shaped to constrain the expansion of the actuating gas bubble in the cavity. This limits expulsion of the actuating liquid into the passage and movement of the conductive liquid along the passage.

Abstract: A substrate, a method for producing a substrate, and a switch incorporating a substrate are disclosed. In one embodiment, the substrate has a first layer, a first electrode deposited on the first layer, and a second layer mated to the first layer. The second layer defines a duct leading from the first electrode to a surface of the second layer opposite the first electrode. A liquid electrode fills at least a portion of the duct.

Abstract: The switch device comprises a pair of cavities, an elongate passage, a non-conductive fluid having a high electrical resistance, a conductive fluid having a high electrical conductivity and an electrical path. The passage is in fluid communication with the cavities and has a substantially elliptical cross-section over at least part of its length. The non-conductive fluid is disposed in each of the cavities. The conductive fluid is located in the passage. The electrical path is changeable between a connected state and a disconnected state by the non-conductive fluid separating the conductive fluid in the passage into non-contiguous conductive fluid portions.

Abstract: The present invention is directed to a photoconductive switch module. The photoconductive switch module comprises a first substrate having light-emitting elements, and a second substrate having photoconductive switch elements, whose number is equal to that of the light-emitting elements. The light-emitting elements face the photoconductive switch elements, so that the photoconductive switch elements are turned on/off in accordance with lighting/extinction of the light-emitting elements. The photoconductive switch module further comprises a third substrate arranged between the first substrate and the second substrate. The third substrate has through holes, whose number is equal to that of the light-emitting elements. Each through hole is positioned between a light-emitting element and a photoconductive switch element facing each other. Drive light emitted from each light-emitting element travels to the photoconductive switch element via the through hole.

Abstract: Pressure-actuated bi-stable optical switching is provided. In this regard, a pressure-actuated bi-stable optical switch includes an optical path and a cavity intersecting the optical path. The cavity defines a first position along the optical path and a second position displaced from the optical path. An index-matching liquid, which exhibits an index of refraction closer to an index of refraction of the optical path than to that of a vacuum, is arranged within the cavity. A pressure generator generates pressure that selective moves the liquid between the first and second positions. Additionally, a potential profile maintains the liquid in the one of the first and second positions to which it was most recently moved while the pressure generator is not generating pressure. Methods, systems and other switches also are provided.

Abstract: The switch device includes first and second cavities, a passage extending between the cavities, a conductive liquid located in the passage and movable therein, a conductive path that includes the conductive liquid, an actuating liquid enclosed in each of the first and second cavities and covering the inner surfaces thereof and an actuating gas enclosed in each of the first and second cavities and existing as a bubble therein. At least one of the cavities includes a constriction element shaped to constrain the expansion of the actuating gas bubble in the cavity. This limits expulsion of the actuating liquid into the passage and movement of the conductive liquid along the passage.

Abstract: The switch device comprises a pair of cavities, an elongate passage, a non-conductive fluid having a high electrical resistance, a conductive fluid having a high electrical conductivity and an electrical path. The passage is in fluid communication with the cavities and has a substantially elliptical cross-section over at least part of its length. The non-conductive fluid is disposed in each of the cavities. The conductive fluid is located in the passage. The electrical path is changeable between a connected state and a disconnected state by the non-conductive fluid separating the conductive fluid in the passage into non-contiguous conductive fluid portions.

Abstract: Pressure-actuated bi-stable optical switching is provided. In this regard, a pressure-actuated bi-stable optical switch includes an optical path and a cavity intersecting the optical path. The cavity defines a first position along the optical path and a second position displaced from the optical path. An index-matching liquid, which exhibits an index of refraction closer to an index of refraction of the optical path than to that of a vacuum, is arranged within the cavity. A pressure generator generates pressure that selective moves the liquid between the first and second positions. Additionally, a potential profile maintains the liquid in the one of the first and second positions to which it was most recently moved while the pressure generator is not generating pressure. Methods, systems and other switches also are provided.

Abstract: The photoconductive switch comprises a first confinement layer, a second confinement layer, a photoconductive layer that includes a doped sub-layer and an undoped sub-layer, a first electrode and a second electrode. The first confinement layer is a layer of a first semiconductor material having a first band-gap energy and a first conductivity type. The second confinement layer is a layer of a second semiconductor material having a second band-gap energy. The photoconductive layer is a layer of a third semiconductor material having a third band-gap energy and a second conductivity type, opposite to the first conductivity type. The photoconductive layer is sandwiched between the first confinement layer and the second confinement layer, and the third band-gap energy is less than the first and second band-gap energies. In the photoconductive layer, the doped sub-layer is in contact with the first confinement layer, and the undoped sub-layer is adjacent the second confinement layer.

Abstract: An electrical contact breaker switch has a cavity or space that forms first and second chambers and a plurality of channels. The switch also has at least two solid electrodes formed with electrode components exposed apart from each other within the cavity. A conductive fluid held within the cavity functions as a contact for putting the electrode components of two specific solid electrodes in a “closed” state when in contiguous form and in an “open” state when in non-contiguous form. A form modification unit, which includes the first and second chambers, modifies the form of the conductive fluid.

Abstract: A PCS that comprises a photo-conductive layer of NB material sandwiched between a top confinement layer and a bottom confinement layer. Both confinement layers are layers of WB material. NB material and WB material are semiconductor materials. NB material has a smaller band-gap energy than WB material. The top confinement layer and the photo-conductive layer have opposite conductivity types. A first electrode and a second electrode, separated from each other by a gap and are located on the surface of the top confinement layer remote from the photo-conductive layer. The photo-conductive layer provides a low-resistance conduction path between the electrodes when the photo-conductive layer is illuminated with incident light of an appropriate wavelength and intensity.

Abstract: Useful life extension for a data storage system in which either or both of read/write probes and storage areas are components subject to wear caused by the access operations. An access counter counts an access count for each component subject to wear. A data exchange module operates in response to the access count for one of the components subject to wear reaching a first threshold to perform a data exchange in which data stored in a first storage area are exchanged with data stored is a second storage area. When the components subject to wear are the storage areas, the first storage area is the storage area whose access count reached the first threshold value, and the second storage area is a storage area whose access count is less than the first threshold value.

Abstract: A high-data density, high-data rate scanning memory device reads and writes data using a plurality of probes. The scanning memory device comprises a memory composed of a matrix of cell arrays each containing a submatrix of memory cells, a plurality of probes having a one-to-one correspondence to each cell array, and a positioning device that operates to simultaneously change the positions of probes relative to the cell arrays. Each of the cell arrays has a cell array status memory for storing information designating whether the cell array is functional or whether the cell array is defective. If the number of defective memory cells detected within each cell array exceeds some predetermined number, the cell array is designated as defective. Defective cell arrays are logically replaced by functional cell arrays. Error correction is applied to the data to reduce reading and writing errors by the scanning memory device and to maintain the integrity of data stored in the memory.

Abstract: A small position detection and positioning device detects relative displacement between two members with high precision. A moving medium-type memory device using such positioning device is also provided. The position detection device includes a linear array of first electrodes at equal pitches on one of the two members that have relative displacement in at least one dimension, and a linear array of at least one second electrode on the other member. The first electrodes are positioned opposite the second electrodes and separated from them by a minute gap. The first electrodes are divided into a first electrode set composed of alternate ones of the first electrodes, and a second electrode set composed of alternate ones of the first electrodes not in the first electrode set. A signal source which applies a first alternating signal to the first electrode set and a second alternating signal that differs in phase by 180.degree.

Abstract: A memory device that comprises a planar memory medium and a probe device mounted opposite the planar memory medium. The probe device includes a substrate having a substrate surface and probe cells arrayed on the substrate surface. Each of the probe cells comprises a probe, an auxiliary electrode and a probe driving circuit. The probe is formed in the substrate, includes part of the substrate surface, and additionally includes a conductive needle projecting towards the memory medium. The conductive needle includes a needle tip adjacent the memory medium. The auxiliary electrode is mounted on the probe, and is located between the probe and the memory medium. The auxiliary electrode is disposed substantially parallel to, and spaced from, the substrate surface. The driving circuit is formed in the substrate and projects from the substrate surface towards the memory medium. The probe driving circuit has outputs electrically connected to the auxiliary electrode and the memory medium.

Abstract: A position detection device that comprises a first substrate, a second substrate, an alternating current (AC) bridge comprised of four variable capacitors, and a detection circuit. The first and second substrates have a flat first electrode surface and a flat second electrode surface, respectively. The second substrate is mounted opposite the first substrate with the first electrode surface opposite the second electrode surface and separated from the second electrode surface by a minute gap. The second substrate and the first substrate are movable relative to one another in the plane of the electrode surfaces. Each of the variable capacitors is composed of a first capacitor electrode located on the first electrode surface and a second capacitor electrode located opposite the first capacitor electrode on the second electrode surface.

Abstract: A high-data density, high-data rate scanning memory device reads and writes data using a plurality of probes. The scanning memory device comprises a memory composed of a matrix of cell arrays each containing a submatrix of memory cells, a plurality of probes having a one-to-one correspondence to each cell array, and a positioning device that operates to simultaneously change the positions of probes relative to the cell arrays. Each of the cell arrays has a cell array status memory for storing information designating whether the cell array is functional or whether the cell array is defective. If the number of defective memory cells detected within each cell array exceeds some predetermined number, the cell array is designated as defective. Defective cell arrays are logically replaced by functional cell arrays. Error correction is applied to the data to reduce reading and writing errors by the scanning memory device and to maintain the integrity of data stored in the memory.

Abstract: A light modulator having the small volume and low power consumption of LCD displays together with the higher resolution and faster response time of CRT displays. The light modulator includes a substrate pair, an opaque light shielding layer, a shutter assembly composed of a shutter plate and a shutter suspension, and electrodes. The substrate pair includes a first substrate and a second substrate positioned parallel to each other and spaced from one another to define a cavity. The opaque light shielding layer is located on one of the substrates, and defines a translucent window. The shutter assembly is located in the cavity. The shutter plate is movably mounted adjacent the window by the shutter suspension. The shutter suspension includes elastic support members disposed between the shutter plate and the substrate pair.