1742results about "Circuit optical details" patented technology

An object of the present invention is to provide a substrate for mounting an IC chip which is a component for optical communication having an IC chip and an optical component integrally provided thereon, which can ensure a short distance between the IC chip and the optical component, which is excellent in electric signal transmission reliability and which can transmit optical signal through an optical path for transmitting optical signal. The substrate for mounting an IC chip of the present invention is a substrate for mounting an IC chip comprising: a substrate and, as serially built up on both faces thereof, a conductor circuit and an interlaminar insulating layer in an alternate fashion and in repetition; a solder resist layer formed as an outermost layer; and an optical element mounted thereto, wherein an optical path for transmitting optical signal, which penetrates the substrate for mounting an IC chip, is disposed.

A reflective element assembly for a mirror assembly of a vehicle includes a reflective element substrate and a conductive trace or layer disposed at a rear surface of the reflective element substrate. A non-conductive layer is applied at the conductive layer and covers at least a portion of the conductive layer and leaves at least some portions of the conductive layer exposed. At least one circuitry component is applied to at least one of the portions of the conductive layer. The circuitry component may comprise a carbon ink resistor printed onto the conductive trace.

A touch sensor device is provided that uses a flexible circuit substrate to provide an improved input device. Specifically, the present invention uses a touch sensor controller affixed to the flexible circuit substrate, which is coupled to a sensor component to provide a flexible, reliable and cost effective touch sensor suitable for a wide variety of applications. In one embodiment the touch sensor uses a flexible circuit substrate that provides relatively high temperature resistance. This allows the touch sensor controller to be affixed using reliable techniques, such as various types of soldering. The sensor component can comprise a relatively low-temperature-resistant substrate that can provide a cost effective solution. Taken together, this embodiment of the touch sensor provides reliability and flexibility at relatively low cost.

According to the present invention, a rearview mirror comprises a first substrate having a front surface and a rear surface, a reflective coating disposed on a surface of the first substrate, and an electronic circuit component secured to the rear surface of the first substrate. The mirror element may be an electrochromic mirror element comprising a transparent second substrate positioned in front of the first substrate. The electronic component secured to the rear surface may be a component of a drive circuit for the electrochromic mirror element. The rearview mirror element may further comprise electrically conductive tracings provided on the rear surface of the first substrate electrically coupled to the electrical component. The tracings may be used to electrically couple the drive circuit to the electrodes of the electrochromic mirror element. The tracings may be deposited on the rear surface using numerous methods including inkjet printing techniques.

Disclosed is an optical printed circuit board (PCB) having a multi-channel optical waveguide, which comprises: an optical waveguide having an optical path for transmitting light beams; a groove for penetrating the optical waveguide; and an optical interconnection block inserted in the groove and connected to the optical waveguide to transmit the light beams, wherein the optical interconnection block includes an optical fiber bundle bent by the angle of 90°. The optical interconnection block connects a plurality of multi-layered optical waveguides to transmit light beams to the optical waveguides. The optical fiber bundle is installed as a medium of the multi-channel optical waveguide in the optical PCB.

An optoelectronics chip-to-chip interconnects system is provided, including packaged chips to be connected on printed-circuit-board (PCB), multiple-packaged chip, optical-electrical(O-E) conversion means, waveguide-board, and PCB. Single to multiple chips interconnects can be possible using this technique. The packaged-chip includes semiconductor-die and its package based on the ball-grid array or chip-scale-package. The O-E board includes the optoelectronics components and multiple electrical contacts. The waveguide board includes electrical conductors transferring signal from O-E board to PCB and the flex optical waveguide easily stackable onto the PCB, to guide optical signal from one chip-to-other chip. The chip-to-chip interconnects system is pin-free and compatible with the PCB. The main advantages are that standard packaged-chip and conventional PCB technology can be used for low speed electrical signal connection. Also, the part of the heat from the packaged chip can be transmitted to PCB through conductors, so that complex cooling system can be avoided.

The present invention provides a device for optical communication comprising: a substrate for mounting an IC chip having a light emitting element and a light receiving element mounted at predetermined positions; and a multilayered printed circuit board having an optical waveguide formed at a predetermined position, which is low in connection loss among the mounted optical components and which has excellent connection reliability. The device for optical communication according to the present invention comprises the substrate for mounting an IC chip and the multilayered printed circuit board, wherein the substrate for mounting an IC chip includes conductor circuits, interlaminar insulating layers and via-holes for connecting the conductor circuits, with the interlaminar insulating layers interposed therebetween, to each other, and a light receiving element and a light emitting element are mounted on the substrate for mounting an IC chip.

Light-emitting diode (LED) packages with improved heat transfer paths for LED dies encased therein when compared to conventional LED packages are provided. For some embodiments, the LED package includes a ceramic substrate having a top cavity with one or more LED dies disposed within and having a bottom cavity for receiving a metallic insert to dissipate heat away from the LED dies. For other embodiments, an LED package is provided that includes a ceramic substrate having a heat spreader coupled to thermal vias filled with a highly thermally conductive composite.

An integrated light and accessory assembly for a vehicle is disclosed. The assembly includes at least one lamp for illumination of a vehicle, and also includes reflective, conductive and insulative portions inside a housing, and a module for controlling or accessorizing the assembly. Also disclosed is a method of manufacturing the assembly. The method includes providing materials for molding or shaping the components of the assembly, selectively etching conductive materials, molding the materials into a desired configuration, connecting a lamp and an accessory module to the conductive portions, and enclosing the components in a housing. A portion of the module may be removed for emergency lighting.

A light emitting assembly includes a metal substrate for dissipating heat from the assembly. The metal substrate includes an electrically insulating layer or coating on at least one side. Circuit traces are applied to the electrically insulating layer using either thick or thin film techniques. At least the ends of the circuit traces include a metallic section to which leads of light emitting elements are soldered or wire-bonded. A metallic section is provided adjacent the light emitting element to transfer heat to the underlying substrate and / or to reflect light from the element away from the substrate. A clear finish retards tarnishing of the reflecting metallic section.

The present invention provides a system, method and apparatus for improved electrical-to-optical transmitters (100) disposed within printed circuit boards (104). The heat sink (110, 200) is a thermal conductive material disposed within a cavity (102) of the printed circuit board (104) and is thermally coupled to a bottom surface (112) of the electrical-to-optical transmitter (100). A portion of the thermal conductive material extends approximately to an outer surface (120, 122 or 124) of a layer (114, 116 or 118) of the printed circuit board (104). The printed circuit board may comprise a planarized signal communications system or an optoelectronic signal communications system. In addition, the present invention provides a method for fabricating the heat sink wherein the electrical-to-optical transmitter disposed within a cavity of the printed circuit board is fabricated. New methods for flexible waveguides and micro-mirror couplers are also provided.

The present invention aims to provide a substrate for mounting an IC chip, on which an optical signal passing region is formed and which can suppress a transmission loss in an optical signal and transmit an optical signal more positively with high reliability. The substrate for mounting an IC chip according to the present invention is a substrate for mounting an IC chip, in which a conductor circuit and an insulating layer are laminated in alternate fashion and in repetition on both faces of a substrate and an optical element is mounted on the substrate. Herein, the substrate for mounting an IC chip includes an optical signal passing region, and a microlens arranged on an end portion of the optical signal passing region on the opposite side from the optical element.

A textile fabric structure having a plurality of microelectronic components, which are arranged in the textile fabric structure, electrically conductive threads, which couple the plurality of microelectronic components to one another, conductive data transmission threads, which couple the plurality of microelectronic components to one another, and electrically nonconductive threads. The conductive threads and the conductive data transmission threads at the edge of the textile fabric structure are each provided with an electric interface and a data transmission interface.

A display device including a wiring substrate having a first substrate layer and a second substrate layer, a conductive adhesive layer configured to cover the wiring substrate, a plurality of semiconductor light emitting devices coupled to the conductive adhesive layer and electrically connected to a first electrode and a second electrode. Further, the first electrode is disposed on the first substrate layer, and the second substrate layer has one surface facing the conductive adhesive layer and the other surface covering the first electrode, and an auxiliary electrode electrically connected to the first electrode and the second electrode are disposed on one surface of the second substrate layer.

A ceramic substrate comprising a metallic layer on its surface, wherein said metallic layer includes: a silver layer containing silver; a gold layer containing gold; and a nickel layer containing nickel, in this order from an outermost layer of said metallic layer.

An optical module. The optical module includes a printed circuit board and an opto-chip. The opto-chip includes a transparent carrier with an optoelectronic device array and an associated integrated circuit array that are flip chip attached to the transparent carrier. The optoelectronic device array and the associated integrated circuit array are interconnected via surface wiring with bond sites. In addition, the associated integrated circuit array extends beyond the transparent carrier to provide direct flip chip attachment of the opto-chip to the printed circuit board.

A hermetically sealed, opto-electronic array housing assembly having a ceramic base, electrical connectors, a metal can, and a glass window. The glass window can support a micro-lens array. The metal can receives the glass window. The electrical impedance of the electrical connectors is beneficially carefully controlled to enable high-speed data communications. A multi-element optical fiber connector can provide for optical communications to and / or from an opto-electronic array contained within the housing.

A light emitting apparatus (8) includes one or more light emitting chips (10) that are disposed on a printed circuit board (12) and emit light predominantly in a wavelength range between about 400 nanometers and about 470 nanometers. The printed circuit board includes: (i) an electrically insulating board (14); (ii) electrically conductive printed circuitry (20); and (iii) an electrically insulating solder mask (22) having vias (24) through which the one or more light emitting chips electrically contact the printed circuitry. The solder mask (22) has a reflectance of greater than 60% at least between about 400 nanometers and about 470 nanometers.

A device for invasive use, comprising a support member comprising a flexible material. The support member comprises a layer of a conductive line or pattern thereon. The support member is formed into an elongated tube shape, and the inside of the support member can be sealed from the outside of the support member. An electrically conductive line or pattern extends on the inside of the tube shaped support member, and the support member may comprise a sensing, stimulating and / or processing element. Furthermore, there is described a manufacturing method for the device, a system where the device is a part of the system and the use of the device for invasive use.

A printed circuit board for coupling surface mounted optoelectric semiconductor devices within a computer system is disclosed. The printed circuit board includes at least one substantially planar surface. There are multiple electrically conductive sites located on the substantially planar surface for connection to a surface mounted semiconductor electronic device. The electrically conductive sites are also connected to electrical interconnects embedded within the printed circuit board. In addition, there are multiple optical pathways terminated at the substantially planar surface for coupling a surface mounted semiconductor optoelectric device.

A light emitting assembly includes a metal substrate for dissipating heat from the assembly. The metal substrate includes an electrically insulating layer or coating on at least one side. Circuit traces are applied to the electrically insulating layer using either thick or thin film techniques. At least the ends of the circuit traces include a metallic section to which leads of light emitting elements are soldered or wire-bonded. A metallic section is provided adjacent the light emitting element to transfer heat to the underlying substrate and / or to reflect light from the element away from the substrate. A clear finish retards tarnishing of the reflecting metallic section.

A build-up structure for chip to chip interconnects and System-In-Package utilizing multi-angle vias for electrical and optical routing or bussing of electronic information and controlled CTE dielectrics including mesocomposites to achieve optimum electrical and optical performance of monolithic structures. Die, multiple die, Microelectromechanical Machines (MEMs) and / or other active or passive components such as transducers or capacitors can be accurately positioned on a substrate such as a copper heatsink and multi-angle stud bumps can be placed on the active sites of the components. A first dielectric layer is preferably placed on the components, thereby embedding the components in the structure. Through various processes of photolithography, laser machining, soft lithography or anisotropic conductive film bonding, escape routing and circuitry is formed on the first metal layer. Additional dielectric layers and metal circuitry are formed utilizing multi-angle vias to form escape routing from tight pitch bond pads on the die to other active and passive components. Multi-angle vias can carry electrical or optical information in the form of digital or analog electromagnetic current, or in the form of visible or non-visible optical bussing and interconnections.

A fiber optic module for transferring data as pulses of light has an optical element with a first light transducer having a straddle mount lead and a second light transducer having a formed or bent signal lead. A first fiber optic receptacle optically couples to the first light transducer and a second fiber optic receptacle optically couples to a second light. A printed circuit board subassembly includes first and second printed circuit boards with an interconnection therebetween to couple to an electrical connector on the first. The first printed circuit board and second printed circuit boards are aligned so that the straddle mount leads couple to contacts on the first and the formed signal lead couple to contacts on the second. One or more electrical components in the fiber optic module process data for communication using light or photons over one or more optical fibers. An outer housing encloses the optical element subassembly and the printed circuit board subassembly. The electrical connector couples external electrical signals to the electrical components.

The present invention provides a device for optical communication comprising: a substrate for mounting an IC chip having a light emitting element and a light receiving element mounted at predetermined positions; and a multilayered printed circuit board having an optical waveguide formed at a predetermined position, which is low in connection loss among the mounted optical components and which has excellent connection reliability.The device for optical communication according to the present invention comprises the substrate for mounting an IC chip and the multilayered printed circuit board, wherein the substrate for mounting an IC chip includes conductor circuits, interlaminar insulating layers and via-holes for connecting the conductor circuits, with the interlaminar insulating layers interposed therebetween, to each other, and a light receiving element and a light emitting element are mounted on the substrate for mounting an IC chip.

Ophthalmic lenses, including contact lenses may be enhanced through the incorporation of both active and passive electrical components. Electrical interconnects and die attachment configurations are required to ensure electrical connectivity between the components and the optic portion of the lens as well as providing a means for mounting planar devices on spherical surfaces. Electrical interconnects and die attachment for powered ophthalmic devices, including contact lenses includes realizing conductive traces on optical plastic, attaching planar dies to spherical surfaces and underfilling, overmolding and light blocking to complete the lens.

An IC chip is provided with a wireless unit for inputting and outputting data by wireless communication, in addition to a logic section, so that the IC chip no longer needs I / O pads, leaving only power supply and ground pads. IC chips can input and output data with one another by wireless communications, which makes it possible to significantly improve the spacing relationships of various chips on a singular or even plurality of substrates.