Abstract: A magnifying device for magnifying an object and displaying the object on a monitor is disclosed. The magnifying device includes a hand held unit or scanner and a base unit. The scanner includes a solid state camera which is mounted in a housing. The scanner includes a focusing control and a zoom control. The focusing and zoom controls are interconnected so that the image will not have to be refocused if the magnification of the image is changed. The camera converts the image to an electrical signal which is sent to the base unit. A mobile holder for the scanner is provided having an upper frame of space apart, horizontally extending arms. The arms extend laterally from the top edge of a vertical side wall. The scanner can be removeably attached between the arms and there by elevated above the object being read. The side wall has a pair of wheels attached to the bottom corners. There is a support member at one corner which extends laterally from the wall and parallel to the support arms.

Abstract: A lateral-emitter electron field emission device structure incorporates a thin film laminar composite emitter structure including two or more films composed of materials having different etch rates when etched by an etchant. In its simplest form, the laminar composite emitter consists of two ultra-thin layers, etched differentially so that a salient remaining portion of the more etch-resistant layer protrudes beyond the less etch-resistant layer to form a small-radius tip. In a preferred form of the laminar composite emitter, it is a multi-layer laminar emitter, of which the most etch-resistant layer is doped-diamond. The diamond layer is doped using one or more N-type dopants. In this preferred emitter structure, the edge of the thin film diamond layer is the dominant electron emitter with a very low (nearly zero) work function. Hence the new device can operate at applied voltages substantially lower than in prior art. The laminar structure may be a sandwich structure with three layers.

Abstract: A fabrication process is disclosed using process steps (S1-S18) similar to those of semiconductor integrated circuit fabrication to produce lateral-emitter field-emission devices and their arrays. In a preferred fabrication process for the simplified anode device, the following steps are performed: an anode film (70) is deposited; an insulator film (90) is deposited over the anode film; an ultra-thin conductive emitter film (100) is deposited over the insulator and patterned; a trench opening (160) is etched through the emitter and insulator, stopping at the anode film, thus forming and automatically aligning an emitting edge of the emitter; and means are provided for applying an electrical bias to the emitter and anode, sufficient to cause field emission of electrons from the emitting edge of the emitter to the anode. The anode film may comprise a phosphor (75) for a device specially adapted for use in a field emission display.

Abstract: A microelectronic light-emitting device (10) is made with dual lateral thin-film emitters (35 and 40) substantially parallel to a substrate (20). A region containing phosphor (50) extends between the two emitters and contacts them. A fabrication process is specially adapted to produce the light-emitting devices and/or arrays of light-emitting devices. The process allows the use of conductive or insulating base or starting substrates.

Abstract: An improved high-frequency field-emission microelectronic device (10) has a substrate (20) and an ultra-thin emitter electrode (30) extending parallel to the substrate and having an electron-emitting lateral edge (110) facing an anode (40) across an emitter-to-anode gap (120). A control electrode (70), having a lateral dimension only a minor fraction of the emitter-to-anode gap width, is disposed parallel to the emitter and spaced apart from the emitter by an insulator (60) of predetermined thickness. A vertical dimension of the control electrode is only a minor fraction of the height of the anode. The control electrode may substantially surround a portion of the anode, spaced from the anode in concentric relationship.

Abstract: A process produces laminar composite lateral-emitter microelectronic devices especially useful in high-resolution field-emission display arrays. The devices incorporate a thin film laminar composite emitter structure including two or more films composed of materials having different etch rates. The laminar composite emitter consists of two or more ultra-thin layers, etched differentially so that a salient remaining portion of the most etch-resistant layer protrudes beyond the less etch-resistant layers to form a small-radius tip. The most etch-resistant layer is preferably diamond doped with one or more N-type dopants. An emitting edge of the laminar composite emitter is first formed by a directional trench etch. During or after fabrication of a trench portion of the structure, a small amount of supporting upper and/or lower layers is removed by a differential etch, such as a plasma etch. This leaves an ultra thin emitter edge or tip.

Abstract: A lateral-emitter electron field-emission display device structure incorporates a thin-film emitter having an emitting edge in direct contact with and extending into a non-conducting or very high resistivity phosphor, thereby eliminating the gap between the emitter and the phosphor. Such a gap has been a part of all field-emission display devices in the prior art. The ultra-thin-film lateral emitter of the new structure is deposited in a plane parallel to the device's substrate and has an inherently small radius of curvature at its emitting edge. A fabrication process specially adapted to make the new structure includes a directional trench etch, which both defines the emitting edge and provides an opening to receive a non-conducting phosphor. This phosphor covers an anode and is automatically aligned in contact with the emitter edge.

Abstract: A lateral-emitter field emission device has a thin-film emitter cathode 50 which has thickness of not more than several hundred angstroms and has an edge or tip 110 having a small radius of curvature. To form a novel display cell structure, a cathodoluminescent phosphor anode 60 is positioned below the plane of the thin-film lateral-emitter cathode 50, allowing a large portion of the phosphor anode's top surface to emit light in the desired direction. An anode contact layer contacts the phosphor anode 60 from below to form a buried anode contact 90 which does not interfere with light emission. The anode phosphor is precisely spaced apart from the cathode edge or tip and receives electrons emitted by field emission from the edge or tip of the lateral-emitter cathode, when a small bias voltage is applied. The device may be configured as a diode, triode, or tetrode, etc.

Abstract: A magnifying device for magnifying an object and displaying the object on a monitor is disclosed. The magnifying device includes a hand held unit and a base unit. The hand held unit includes a solid state camera which is mounted in a housing. The housing is supported above the text to be enlarged by a set of legs having rollers extending therebetween, to allow the hand held unit to be easily and smoothly moved across the text. The hand unit includes a focusing control and a zoom control. The focusing and zoom controls are interconnected so that the image will not have to be refocused if the magnification of the image is changed. The camera converts the image to an electrical signal which is sent to the base unit. The base unit includes inverting circuitry to convert the image from black on white to white on black, if desired. The base unit can be connected either to video monitor or a standard television.

Abstract: A lateral-emitter field emission device has a thin-film emitter cathode 50 which has thickness of not more than several hundred angstroms and has an edge or tip 110 having a small radius of curvature. To form a novel display cell structure, a cathodoluminescent phosphor anode 60 is positioned below the plane of the thin-film lateral-emitter cathode 50, allowing a large portion of the phosphor anode's top surface to emit light in the desired direction. An anode contact layer contacts the phosphor anode 60 from below to form a buried anode contact 90 which does not interfere with light emission. The anode phosphor is precisely spaced apart from the cathode edge or tip and receives electrons emitted by field emission from the edge or tip of the lateral-emitter cathode, when a small bias voltage is applied. The device may be configured as a diode, triode, or tetrode, etc.

Abstract: An improved high-frequency field-emission microelectronic device (10) has a substrate (20) and an ultra-thin emitter electrode (30) extending parallel to the substrate and having an electron-emitting lateral edge (110) facing an anode (40) across an emitter-to-anode gap (120). A control electrode (70), having a lateral dimension only a minor fraction of the emitter-to-anode gap width, is disposed parallel to the emitter and spaced apart from the emitter by an insulator (60) of predetermined thickness. A vertical dimension of the control electrode is only a minor fraction of the height of the anode. The control electrode may substantially surround a portion of the anode, spaced from the anode in concentric relationship.

Abstract: A field emission device (10) is made with a lateral emitter (100) substantially parallel to a substrate (20) and with a simplified anode stucture (70). The lateral-emitter field-emission device has a thin-film emitter cathode (100) which has a thickness not exceeding several hundred angstroms and has an emitting blade edge or tip (110) having a small radius of curvature. The anode's top surface is precisely spaced apart from and below the plane of the lateral emitter and receives electrons emitted by field emission from the blade edge or tip of the lateral-emitter cathode, when a suitable bias voltage is applied. A fabrication process is disclosed using process steps (S1-S18) similar to those of semiconductor integrated circuit fabrication to produce the novel devices and their arrays. Various embodiments of the fabrication process allow the use of conductive or insulating substrates (20) and allow fabrication of devices having various functions and complexity.

Abstract: A lateral-emitter electron field-emission display device structure incorporates a thin-film emitter having an emitting edge and extending into in direct contact with a non-conducting or very high resistivity phosphor, thereby eliminating the gap between the emitter and the phosphor. Such a gap has been a part of all field-emission display devices in the prior art. The ultra-thin-film lateral emitter of the new structure is deposited in a plane parallel to the device's substrate and has an inherently small radius of curvature at its emitting edge. A fabrication process specially adapted to make the new structure includes a directional trench etch, which both defines the emitting edge and provides an opening to receive a non-conducting phosphor. This phosphor covers an anode and is automatically aligned in contact with the emitter edge.

Abstract: In all-optical networks, optical switching and routing become the most important issues for interconnecting the transport network layers. This invention describes a novel tunable optical add/drop filter for the all-optical wavelength-division-multiplexing (WDM) network applications. This filter can add or drop part of the high transmission capacity signals of a WDM link. It can be used to decentralized access point in the access network or as small core network node to realizing branching points in the network topology. It works in both wavelength and space domains. It has the advantages of: 1) High throughput and low voltage operation; 2) Wide tuning range and therefore, high channel capacity; 3) High isolation and high directivity between input and output ports; 4) Compact device packaging is possible as compares to the conventional grating and mechanical switching type of add/drop filter; 5) Multiple ports add/drop tunable filters can be realized with this invention to interconnect multiple WDM networks.

Abstract: An observer is presented, through a pair of viewing glasses, a field/frame multiplexed, synthesized three-dimensional or stereoscopic image on single monitor generated from a two-dimensional monocular video signal. The field/frame multiplexed, synthesized 3D image is generated in a converter. A controller controls the left and right eye vision of the glasses along an unobstructed path without need of any connecting wires. A wide range of input sources can provide the 2D input video signal for conversion. The resulting synthesized 3D image is especially suited for medical and other purposes which require realistic, accurate and visually comfortable 3D visualization of video images, as for example in minimally-invasive surgery to allow complex navigational and manipulational procedures carried out over a continuous period of many hours.

Abstract: An apparatus for detecting concealed objects, such as explosives, drugs, or other contraband is disclosed. The apparatus uses CT scanning to identify concealed objects with a density corresponding to the density of target objects such as explosives or drugs. To reduce the amount of CT scanning required, a number of prescanning approaches are disclosed. Based upon the prescan data, selected locations for CT scanning are identified. CT scanning is undertaken at the selected locations. The resultant CT scan data is utilized to automatically identify objects of interest. This identification of objects may be verified through further automatic analysis of such attributes as shape, texture, context, and X-ray diffraction. Finally, the objects of interest may be reconstructed and displayed on a computer monitor for visual analysis by an operator.

Abstract: M-ary angle modulation is used to record digital data at high density on a disk. In one embodiment, data symbols are encoded by assigning each data symbol a phase representation in terms of a carrier signal, the disk is physically altered in such a manner as to represent the carrier signal, and, at defined intervals, a phase angle of the carrier signal is changed by one of M of possible phase increments, where M equals two to the power of a number of data bits in a data symbol. M data bits are therefore recorded per each of the defined intervals. In another embodiment, a frequency of the carrier signal is changed to have one of M possible frequencies.

Abstract: A system for retrieving information on a random basis from a disc having the information thereon in a spiral path around the disc. The system includes a turntable rotatable about a central spindle and adapted to support the disc thereon. An arm housing is fixedly mounted over the turntable and contains printed circuit boards having some of the electrical circuitry for the system. Also in the arm housing is a rectangular frame like cartridge holder which supports a cartridge having a stylus therein. The stylus is adapted to ride on the disc to read out the information from the disc. A piston is connected to the cartridge holder and extends through the arm housing. A motor is connected to the piston and is adapted to move the piston so that the cartridge holder is moved with respect to the arm housing and the stylus moves radially along the disc. The motor moves the stylus over the short distance of the radius so as to quickly and easily obtain random access to the information in the disc.