Abstract: Resistive bridges can connect many ring electrodes in an electro-active lens with a relatively small number of buss lines. These resistors are usually large to prevent excessive current consumption. Conventionally, they are disposed in the same plane as the ring electrodes, which means that the ring electrodes are spaced farther apart or made discontinuous to accommodate the resistors. But spacing the ring electrodes farther apart or making them discontinuous degrades the lens's optical quality. Placing the ring electrodes and resistors on layers separated by an insulator makes it possible for the ring electrodes to be closer together and continuous with resistance high enough to limit current consumption. It also relaxes constraints on feature sizes and placement during the process used to make the lens. And because the resistors and electrodes are on different planes, they can be formed of materials with different resistivities.

Abstract: Certain exemplary embodiments can provide a system, machine, device, manufacture, circuit, composition of matter, and/or user interface comprising and/or related to a tunable electro-optic lens device comprising a first substrate comprising a first electrode layer that comprises a first plurality of ring electrodes that form a first resistive divider network, and a second substrate comprising a second electrode layer.

Abstract: Certain exemplary embodiments can provide a system, machine, device, manufacture, circuit, composition of matter, and/or user interface comprising and/or related to a tunable electro-optic lens device comprising a first substrate comprising a first electrode layer that comprises a first plurality of ring electrodes that form a first resistive divider network, and a second substrate comprising a second electrode layer.

Abstract: An electro-active lens is presented which utilizes a surface relief structures and an electro-active material, with a change in refractive index facilitating the change in optical properties. A molded structure and a liquid crystal are used to form a diffractive lens. In addition to the classical approach of utilizing diffractive optics and multiple Fresnel zones to form a lens, an additional structure is placed between Fresnel zones in order to improve the diffraction efficiency across the visible spectrum, and reduce chromatic aberration.

Abstract: Resistive bridges can connect many ring electrodes in an electro-active lens with a relatively small number of buss lines. These resistors are usually large to prevent excessive current consumption. Conventionally, they are disposed in the same plane as the ring electrodes, which means that the ring electrodes are spaced farther apart or made discontinuous to accommodate the resistors. But spacing the ring electrodes farther apart or making them discontinuous degrades the lens's optical quality. Placing the ring electrodes and resistors on layers separated by an insulator makes it possible for the ring electrodes to be closer together and continuous with resistance high enough to limit current consumption. It also relaxes constraints on feature sizes and placement during the process used to make the lens. And because the resistors and electrodes are on different planes, they can be formed of materials with different resistivities.

Abstract: An electrical receptacle for electrical connection to insulated electrical conductors comprises a dielectric housing (12) including a first housing section (22) and a second housing section (24); first and second electrical contact members (38, 40) disposed in the dielectric housing (12) and having first contacts (38b, 40b) in alignment with slots (26, 28) of the dielectric housing and second contacts (38a, 40a) in alignment with openings (58) of the dielectric housing including insulation-displacement contacts; and conductor-moving members (16, 18) associated with the insulation-displacement contacts-for moving the insulated electrical conductors into the insulation-displacement contacts thereby effecting electrical connections between the insulation-displacement contacts and the insulated electrical conductors.

Abstract: An electrical component (10, 110, 210, 310) for electrically connecting insulated electrical conductors (56) thereto comprises a dielectric housing (12, 112, 212, 312) including a first housing section (20, 118, 218, 318) and a second housing section (22, 120, 220, 320), first and second electrical contact members (42, 44, 158, 160, 240, 242, 334, 336) disposed in the dielectric housing and having first contacts (42a, 44a, 158a, 160a, 240a, 242a, 334a, 336a) extending into the second housing section and second contacts (42b, 44b, 158b, 160b, 240b, 242b, 334b, 336b) positioned within the first housing section, insulation-displacement contacts (42a, 44a, 158a, 160a, 248, 348) as part of the first contacts along which the insulated electrical conductors are positioned, and conductor-moving members (16, 18, 154, 156, 250, 346) for engaging the insulated electrical conductors and moving them into the insulation-displacement contacts thereby forming electrical connections between the insulation-displacement contact

Abstract: The invention is directed to a bus bar contact having a body with two mating ends. One of the mating ends has a tab contact portion. The other of the mating ends having a receptacle contact portion. The receptacle contact portion has a plurality of resilient fingers for providing an electrical interface. The resilient fingers are stamped and formed from the body member wherein adjacent resilient fingers are sheared from each other thereby removing no material from between the adjacent resilient fingers.

Abstract: The invention comprises a power tap connector of the type for terminating by insulation displacement a pair of conductors. The connector includes a housing for receiving at least a pair of upstanding IDC terminals. A pivotally mounted conductor wire carrier has front and rear faces arranged on the housing. The wire carrier is pivotal from a first conductor unterminated position to a second conductor terminated position. The wire carrier has a conductor receiving opening extending from the front face to the rear face for each the IDC terminal. An IDC terminal receiving slot is in communication with each opening, whereby an insulated conductor may be positioned for termination to a corresponding IDC terminal within the opening by entry thereto through either the front face or the rear face.

Abstract: A wire carrier (100,102) for a NID module (10) for enabling termination of premise wiring tip and ring wires (22,24) to terminals (38,40) of the module for interconnection with circuits of the telephone service provider. Circuits of a circuit element (30) interconnect terminals (38,40) to contacts (36) of a jack (32) exposed for connection to a plug during test and otherwise shunted for in-service use. Each wire carrier preferably terminates both tip and ring wires (22,24) of a cable and is pivotable from a wire-receiving position to a wire-terminating position by a pivot section (104) to urge the wires (22,24) into slots (132) of terminals (38,40).

Abstract: An improved tool is disclosed for joining the adjacent ends of pipes, conduits, and like tubular members through the use of explosively propelled swaging members. The tool includes a jacket assembly defining a closed chamber having a die at one end thereof and a die assembly which is received in the chamber. Both the die assembly and jacket assembly are substantially cylindrical to encompass end portions of the tubular members to be joined. The masses of the die assembly and of the jacket assembly are substantially equal so that, when the explosive propellant is ignited, they travel at substantially equal speeds in opposite directions with the die faces travelling towards one another to effect a swaging of a sleeve connector on the respective ends of the tubular members or bell configuration of one member onto a straight end of the adjacent member.