Abstract: A phase spatial light modulator composed of a liquid crystal memory cell and a liquid crystal polarization switch. The liquid crystal memory cell having phase information recorded during the fabrication process thereby affecting the liquid crystal material contained within the cell. The liquid crystal polarization switch capable of perpendicularly rotating the polarization of light impinging upon the liquid crystal polarization switch, prior to passage through the liquid crystal memory cell in response to an applied voltage.

Abstract: Monolithic integrated transistors and a light emitting diode matrix epitaxially grown on a semiconductor substrate. The matrix includes a plurality of LEDs organized into rows and columns, the LEDs being formed of layers of semiconductor material epitaxially grown on the substrate. A row driver for each row includes a transistor coupled to the matrix and a column driver for each column includes a complementary transistor coupled to the matrix. The transistor and the complementary transistor are each an HBT including layers of semiconductor material positioned on the semiconductor material forming the matrix.

Abstract: A stack (103) of distributed Bragg reflectors is disposed on the surface (105) of a semiconductor substrate (102). The stack (103) includes a plurality of alternating layers of material having alternating refractive indexes with the stack (103) having a first dopant type. A first cladding region (104) is disposed on the stack (103) with an active area (106) disposed on the first cladding region (104). The active area (106) includes layers of indium aluminum gallium phosphide, indium gallium arsenide phosphide, and indium aluminum gallium phosphide. A second cladding region (107) is disposed on the active area (106) with a stack (108) of distributed Bragg reflectors disposed on cladding region (107). A contact region (109) is disposed on the stack (108).

Abstract: A method of planarizing wide bandgap semiconductor devices selected from a group including SiC, GaN and diamond having a mesa defined thereon by a trench with a depth of 1 to 2 micrometers and a width of 2 to 10 micrometers. A layer of dielectric material is deposited on the substrate overlying and surrounding the mesa, to a height approximately equal to the height of the mesa and the dielectric material is etched from atop the mesa and from a surrounding area. Layers of spin on glass are deposited to fill the surrounding area and etched to achieve a planar surface including the mesa and the layer of dielectric material.

Abstract: An ESD sensor includes a plurality of layers of dielectric material positioned on a substrate, each having a different thickness, a first contact positioned adjacent each of the plurality of layers and a plurality of second contacts, one each positioned on each layer of the plurality of layers of dielectric material. Each different thickness of each individual layer of dielectric material is formed to provide a specific voltage at which an electrical short will occur between the first and second contacts when an ESD appears thereacross, so that the sensor provides an indication of a range of voltages.

Abstract: A method of fabricating an LED array and stacked driving circuitry includes sequentially forming layers of material on the surface of a substrate, the layers cooperating to emit light when activated. An insulating layer is positioned on the layers and divided into LEDs arranged in an array of rows and columns. Row and column driver circuits are formed on the insulating layer overlying the array by patterning portions of recrystallized amorphous silicon on the insulating layer, depositing a gate insulator layer and a gate metal layer on each of the portions to form an MOS gate, implanting a source and drain in each of the portions, using the MOS gate as a self-aligned mask, and forming contacts for the power terminals and the MOS gate, and coupling each LED in the array to the row and column driver circuits.

Abstract: An optical smart card (10) including a microchip (14) having information stored thereon, an optical holographic sensor pad (16) capable of detecting and collecting light beams emitted from a remote reader/transmitter (52), a light source (18) capable of emitting dataelectronic information contained on the microchip (14) back to the remote reader/transmitter (52) and electronics (20) connected to the sensor pad (16), the light source (18) and the microchip (14).

Abstract: A field emission display (100, 200, 300) and a method of making the same are disclosed. The field emission display (100, 200, 300) includes an anode (110, 210, 310) having a plurality of cathodoluminescent deposits (120, 220, 320), a back plate (185, 285, 385) including a cathode (130, 230, 330) having a plurality of field emitters (140, 240, 340) and being affixed to a cathode reinforcement member (170, 270, 370), and a plurality of side members (150, 250, 350) disposed between the anode (110, 210, 310) and the cathode (130, 230,330) and hermetically affixed thereto. The thicknesses of the anode (110, 210, 310) and the back plate (185, 285, 385) are sufficient to provide the structural support necessary to maintain the mechanical integrity of the field emission display (100, 200, 300).

Abstract: A method of fabricating a multi-chip package including an aluminum silicon substrate with an aluminum nitride layer thereon forming an electrically insulated surface and aluminum heat conductive areas positioned on the insulated surface. Conductors on the surface of the substrate defining mounting areas and external connections with each mounting area positioned adjacent an associated one of the heat conductive areas and a semiconductor chip mounted in each mounting area. Heat conductive elements connected to the rear surface of each chip and to the associated one of the plurality of heat conductive areas, and each chip encapsulated with reworkable encapsulant.

Abstract: A phase spatial light modulator composed of a liquid crystal cell having molecular orientation recorded during the fabrication process as a direct result of a photochemical reaction exerted upon the liquid crystal material, a mechanically-induced change of a liquid crystal alignment layer, or by varying a plurality of polymer materials that compose the liquid crystal alignment layer, thereby affecting the liquid crystal material contained within the cell. The modulator, or scanner, thereby capable of altering the phase, thus steering light passing therethrough. During operation, the liquid crystal molecules deflect the light beam passing therethrough based on their orientation as recorded during fabrication when the applied voltage is "OFF" or in an altered state when the applied voltage is "ON".

Abstract: A light emitting diode display package and method of fabricating a light emitting diode (LED) display package including a light emitting diode array on a substrate, having row and column connection pads routed to display connection pads positioned on an uppermost surface of the LED array device, a separate silicon driver device having connection pads routed to an uppermost surface, positioned to cooperatively meet those of the LED device when properly registered, the LED device flip chip bump bonded to the driver device using standard C5 DCA, an underfill layer positioned between the space defined by the LED device and the driver device. The LED display and driver device package subsequently having selectively removed the substrate onto which the LED array was initially formed. The light emitted from the LED display device, being emitted through the remaining indium-gallium-aluminum-phosphide (InGaAlP) epilayer of the LED device.

Abstract: A system for indicating an angular position of an object includes a photoemitter (205) producing radiation. A level detection device (210) contains a movable body (220) in a medium (215) occupying a location dependent on a gravitational angle of the object. The movable body (220) has a different degree of absorption than the medium (215). A photodetector (235) positioned such that the level detection device (210) is between the photoemitter (205) and the photodetector (235) detects an amount of the radiation based on the location of the movable body (220). The amount of the radiation detected indicates the angular position of the object.

Abstract: A lateral gate, vertical drift region transistor including a drain positioned on one surface of a substrate and a doped structure having a buried region therein positioned on the other surface of the substrate. The buried region defining a drift region in the doped structure extending vertically from the substrate and further defining a doped region in communication with the drift region and adjacent the surface of the doped structure. A source positioned on the doped structure in communication with the doped region. An insulating layer positioned on the doped structure with a metal gate positioned on the insulating layer so as to define an accumulation region extending laterally adjacent the control terminal and communicating with the drift region and the source.

Abstract: A phase spatial light modulator composed of a first liquid crystal cell and one or more additional liquid crystal cells. Each of the liquid crystal cells is positioned so that their extraordinary optical axis (N.sub.e) lies orthogonal to the next liquid crystal cell, and the group of cells is positioned along the optical axis of light emitted by an image source. The modulator, or scanner, thereby capable of steering substantially 100% of unpolarized light therethrough. The modulator intended for use within a display system additionally composed of an image source, driver/control circuitry and an optical magnification system. In operation, an external stimulus is applied, such as a voltage supplied by an external power source, thereby spatially changing the phase of light emitted therethrough. The scanning action enhances display resolution of the generated resultant image without an increase in the number of pixels of the image source.

Abstract: A first layer of non-magnetic material is positioned on a layer of an oxide of a magnetic material (e.g. NiO). First and second layers of magnetic material are stacked in parallel, overlying relationship and separated by a second layer of non-magnetic material sandwiched therebetween to form a magnetic memory cell. The magnetic memory cell is positioned on the first layer of nonmagnetic material so as to sandwich the first nonmagnetic layer between the oxide and the first magnetic layer of the cell. The first layer of non-magnetic material has a thickness (e.g. approximately 7 .ANG.) which prevents the oxide from pinning the first layer of magnetic material and adapts the first layer of magnetic material to the layer of oxide so as to increase the GMR ratio of the magnetic memory cell.

Abstract: An organic light emitting device is positioned on an optically transmissive supporting substrate and includes a layer of ITO positioned on a planar surface of the substrate. A layer of hole transporting material with fluorescent dye molecules as fluorescent centers is supported on the layer of ITO, directly or with other layers, e.g. a hole injecting layer, therebetween. A layer of electron transporting material with fluorescent dye molecules as fluorescent centers is positioned on the hole transporting material and a layer of low work function metal is positioned on the layer of electron transporting material.

Abstract: An organic electroluminescent light emitting display device includes layers of organic electroluminescent material (24) (28) disposed between electrodes (12), (34) (38) for emitting an optical effect. The layers (24) (28) provide discrete electroluminescent pixels which are electrically isolated from one another by wall structures (16) (18) (20). The wall structures are preferably fabricated of dielectric materials. Further, the wall structures are characterized by the width in which a middle portion thereof is narrower than the top portion or the base portion.

Abstract: An organic light emitting device capable of emitting different colors and including a first layer of emissive material designed to emit light of a first color and a second layer of emissive material designed to emit light of a second color. The device is activated to emit light of the first or second colors by causing different current densities to flow through the device such that the emitting zone is positioned in the first light emitting layer, thereby emitting light of a first color, or in the second light emitting layer, thereby emitting light of the second color.

Abstract: A method of passivating organic devices positioned on a supporting substrate including the steps of overcoating the organic device with a low temperature deposited film of dielectric material, and sealingly engaging an inorganic layer over the dielectric material so as to substantially hermetically seal the organic device. In a typical embodiment, the dielectric layer is SiO.sub.2 and the inorganic layer is a metal can.

Abstract: A power monitoring system including a vertical cavity surface emitting laser generating an emission. A beam splitter optically positioned to receive the emission and split the emission into a first portion and a second portion. A monitor optically positioned to receive the first portion of the emission. An output of the monitor is used to control emissions of the vertical cavity surface emitting lasers.