Class / Patent application number | Description | Number of patent applications / Date published |
398200000 | Including optical waveguide | 56 |
20080240734 | Multimode Optical Transmission Device - An optical transmitting circuit ( | 10-02-2008 |
20080298814 | Optical Transmitter for Computing Applications - A compact optical transceiver is provided in which a substrate provides for an alignment surface for optical fibers and a lens assembly provides the necessary optical paths for coupling to photodiode and photodetector structures. Appropriate electrical connections on the substrate enable the substrate to be directly connected to a printed circuit board, grid array socket, and the like. | 12-04-2008 |
20090028579 | FIBER OPTIC LINK HAVING AN INTEGRATED LASER AND PHOTODETECTOR CHIP - A fiber optic communications link is disclosed that can include first and second nodes operably connected by a multi-mode optical fiber and that utilizes two distinct optical wavelengths for enabling the bidirectional transfer of data via the optical fiber between the first and second nodes. Each node can include an integrated transmitter/receiver chip that includes a substrate, an optical receiver or transmitter, a filter, and an optical transmitter or receiver. The transmitter of the chip at the first node can be configured to transmit, via the optical fiber, optical data on one wavelength for conversion to an electrical signal by the receiver of the chip at the second node. Simultaneously, the transmitter of the chip at the second node can be configured to transmit, via the optical fiber, optical data on another wavelength for conversion to an electrical signal by the receiver of the chip at the first node. | 01-29-2009 |
20090052909 | OPTICAL COMMUNICATION MODULE AND OPTICAL SIGNAL TRANSMISSION METHOD - One or more one-dimensional array-shaped photoelectric conversion modules | 02-26-2009 |
20090067853 | Device for transmitting and receiving DVI video over a single fiber optic interconnect - A transmitting device includes a housing, a multichannel transmitter optical subassembly, a microcontroller, and a DVI connector. The housing has only one optical port, where the only one optical port is adapted to receive only one optical fiber. The multichannel transmitter optical subassembly is mechanically associated with the housing. The microcontroller is electrically associated with the multichannel transmitter optical subassembly. The DVI connector is mechanically associated with the housing. The transmitting device is adapted to convert at least four electrical TMDS signals into optical paths that are transmittable over the only one optical fiber. A receiving device is similar to the transmitting device, however, in contrast to the transmitting device, the receiving device includes a multichannel receiver optical subassembly, and wherein the receiving device is adapted to convert multiple colored wavelengths into at least four electrical TMDS signals. | 03-12-2009 |
20090169219 | SIGNAL TRANSMISSION DEVICE - Photoelectric converter-sealed members | 07-02-2009 |
20090169220 | ADAPTIVE OPTICAL SIGNAL PROCESSING WITH MULTIMODE WAVEGUIDES - Optical signals are passed in an optical medium using an approach that facilitates the mitigation of interference. According to an example embodiment, a filtering-type approach is used with an optical signal conveyed in an optical fiber, such as a multimode fiber (MMF) or a multimode waveguide. Adaptive spatial domain signal processing, responsive to a feedback signal indicative of data conveyed in the multimode waveguide, is used to mitigate interference in optical signals conveyed in the multimode waveguide. | 07-02-2009 |
20090252503 | OPTICAL TRANSMISSION MODULE AND OPTICAL TRANSMISSION SYSTEM - An optical transmission module includes one or more transmission optical devices for transmitting an optical signal L | 10-08-2009 |
20090263143 | OPTICAL COMMUNICATION INTEGRATION - An integrated circuit die has a transistor circuitry section for implementing information handling operations. Optical circuitry is within the single semiconductor die. The optical circuitry includes a laser transmitter and is operably coupled to the transistor circuitry section. The transistor circuitry section originates information. The optical circuitry transmits the information in a laser beam through a wave guide to the edge of the integrated circuit die. | 10-22-2009 |
20090317091 | LASER TRANSMITTING AT AUTOMATICALLY VARYING WAVELENGTHS, NETWORK INTERFACE UNIT AND SYSTEM INCLUDING THE LASER, AND METHOD OF AUTOMATICALLY VARYING THE WAVELENGTH OF A LASER - A laser unit, usable in a network interface unit (NIU), that includes a laser adapted to generate an optical signal having a wavelength, a temperature control system for establishing a temperature of the laser and a controller functionally connected to the temperature control system for setting the temperature, the controller configured to automatically vary the temperature between a high temperature and a low temperature different than the high temperature. Also an NIU and a system of NIU's including the laser and an associated method of controlling the laser. | 12-24-2009 |
20090324256 | Optical transmitter - In an optical transmitter, a laser emits light. A laser driving controller controls driving of the laser by superimposing modulation signals on laser driving signals to generate laser driving superimposed signals and by applying the laser driving superimposed signals to the laser to cause wavelength fluctuations in laser output light to suppress nonlinear optical phenomena during optical fiber transmission. An optical power variable controller variably controls a power of the laser output light. An optical fluctuation compensator suppresses optical fluctuations by monitoring output light from the variable controller to detect optical fluctuations accompanying wavelength fluctuations from monitoring results and by controlling a gain of the variable controller. | 12-31-2009 |
20090324257 | OPTICAL TRANSMISSION APPARATUS, OPTICAL TRANSMISSION SYSTEM AND COMMUNICATION METHOD THEREIN - An optical transmitting station changes a power level of control signal light having a first frequency at a second frequency lower than the first frequency, and transmits the control signal light whose power level has been changed to an optical receiving station through an optical transmission line. The optical receiving station monitors whether signal light components of the second frequency are received through the optical transmission line. | 12-31-2009 |
20100028022 | MULTI-LEVEL OPTICAL DATA COMMUNICATION CIRCUIT - A driver circuit is coupled to an optical waveguide transmitter. The driver circuit has a current generator that is in series with the transmitter, and a current robbing circuit is coupled to the transmitter. The current robbing circuit is to divert first and second amounts of current from the transmitter, in accordance with predetermined values of first and second bit streams, respectively, in which data is received to be transmitted. Other embodiments are also described and claimed. | 02-04-2010 |
20100150579 | Semiconductor Optical Element, Semiconductor Laser Using the Semiconductor Optical Element, and Optical Transponder using the semiconductor Laser - In order to realize transition from a non-reflective state to a state in which only a light with a target wavelength can be reflected with a high wavelength selectivity, a semiconductor optical element includes an n-type substrate, an n-type clad layer formed in a part of the n-type substrate itself or upward of the n-type substrate, a p-type clad layer formed upward of the n-type substrate, a guide layer, formed between the p-type clad layer and the n-type clad layer, for waveguiding a light, first and second electrodes respectively formed on the bottom surface of the n-type substrate and the upper surface of the p-type clad layer, and a plurality of electric current regulating members provided in the vicinity of the guide layer and regularly arranged along a light waveguide direction in the guide layer. The plurality of electric current regulating members show a refractive index approximately the same as a surrounding object, provide an even electric current density distribution in the guide layer along the light waveguide direction in the guide layer in a state in which the electric current has been injected in between the first and second electrodes, and generate an even distribution of the refractive index in the guide layer along the light waveguide direction in the guide layer based on the even electric current density distribution. Thereby, the guide layer reflects a light with a wavelength, which is determined in accordance with the even refractive index distribution, of the incident lights. | 06-17-2010 |
20100158540 | OPTICAL MODULE, MANUFACTURING METHOD THEREOF, AND OPTICAL TRANSMITTER - An optical module including a first optical coupler; a second optical coupler; a first optical waveguide; a second optical waveguide; a first electrode provided on the first optical waveguide; a second electrode provided on the second optical waveguide; a short electrode shorter than the first and second electrodes and provided on the second optical waveguide; and a first high-frequency connector and a second high-frequency connector; wherein, the short electrode provided on the second optical waveguide is coupled to the second high-frequency connector; and the first electrode provided on the first optical waveguide is coupled to the first high-frequency connector. | 06-24-2010 |
20100266294 | Multi-Channel Optical Rotary Transmission Device with High Return Loss - An optical rotating data transmission device comprises a first collimator arrangement for coupling-on first light-waveguides, and a second collimator arrangement for coupling-on second light-waveguides, which is supported to be rotatable relative to the first collimator arrangement about a rotation axis. A Dove prism is provided between the collimator arrangements as a derotating element. Furthermore, the collimator arrangements pre provided with adapter elements having rotationally symmetrical conical faces. Prism adapter elements are disposed on the end faces of the Dove prism and have prism adapter elements on the sides facing the collimator arrangements. These also have rotationally symmetrical conical faces with a surface configuration that is inverse to that of the adapter elements of the collimator arrangements. | 10-21-2010 |
20110069973 | EDGE-COUPLED OPTICAL PROXIMITY COMMUNICATION - An optical module is described. This optical module includes at least two optical devices that communicate with each other using edge-to-edge optical coupling of an optical signal between optical components in the two optical devices. Note that the edge-to-edge optical coupling may occur without mode converters at edges of either of the optical devices. Furthermore, the edge-to-edge optical coupling may be facilitated by an alignment substrate, which is mechanically coupled to the two optical devices. This alignment substrate aligns the edges of the two optical devices so that they are approximately parallel to each other, and aligns the optical components in the two optical devices. | 03-24-2011 |
20110069974 | TEXTILE-TYPEINTERFACE DEVICES FOR OPTICAL COMMUNICATION IN WEARABLE COMPUTING SYSTEM - Both ends of an interface may each be configured by an interface device including a light emitting unit that emits light into a textile, a light diffusion unit that widely diffuses the emitted light onto the textile and extends a light receiving range of a light receiving unit, and a light receiving unit for receiving an optical signal of the other party unlike the existing method using electromagnetic inductive coupling in the wearable computing system and a method of performing communication by using light such as infrared rays, visible light, laser, or the like as a medium is provided. | 03-24-2011 |
20110194859 | OPTICAL TRANSMITTER - An optical transmitter includes three or more emission optical fibers that are three-dimensionally arranged, a single reception optical fiber, and an optical path converting component to optically couple the emission optical fibers to the reception optical fiber. The optical path converting component includes optical transmission portions that are optically coupled to the three or more emission optical fibers one to one, respectively, and optically coupled commonly to the single reception optical fiber. Entry ends of the optical transmission portions are aligned with exit ends of the three or more emission optical fibers, respectively. Exit ends of the optical transmission portions are aligned, as a whole, with an entry end of the single reception optical fiber. The exit ends of the optical transmission portions are arranged substantially parallel to one another and in closer proximity to one another than the entry ends of the optical transmission portions. | 08-11-2011 |
20110243574 | MULTIMODE OPTICAL COMMUNICATION - An optical transmitter includes a set of optical waveguides and first, second, and third optical modulators. Output ends of the optical waveguides of the set form a two-dimensional array capable of end-coupling the optical waveguides of the set to a multimode optical fiber in response to the array being located to optically face one end of the multimode optical waveguide. The first optical modulator is optically connected to a first of the optical waveguides of the set, and each of the second and third optical modulators is optically connected to the second and third of the optical waveguides of the set. The set of optical waveguides is configured to provide a coupling matrix of rank three or more between the optical modulators and optical propagation modes in the multimode optical fiber. | 10-06-2011 |
20110280586 | Optical power transmission packeting systems and methods - A system for delivering optical power over an optical conduit includes at least one optical power source delivering optical power to multiple outlet nodes in accordance with a multiple power access methodology. | 11-17-2011 |
20110293291 | System and Method for Acquiring Data of Multi-Channel Signal - A system for acquiring data of a multi-channel signal includes a channel-voltage transmission module disposed in a shield room blocking electromagnetic waves, connected with a plurality of channels from which analog signals are output, and configured to generate a serial digital signal having information about an analog signal and information about a channel from which the analog signal is output, and an optical fiber cable through which the serial digital signal is transmitted from the channel-voltage transmission module to the outside of the shield room. | 12-01-2011 |
20120114340 | OPTICAL TRANSMITTER AND INTERCONNECTING CIRCUIT BOARD - An optical transmitter including: an optical module; an interconnecting circuit board configured to be electrically coupled to the optical module; and a printed circuit board configured to be electrically coupled to the interconnecting circuit board; wherein the interconnecting circuit board includes: a coplanar waveguide; and a microstrip line including a signal wiring line extended from an end of the coplanar waveguide and a ground wiring line, wherein the width of the signal wiring line is narrower than the width of a signal wiring line of the coplanar waveguide, and the spacing between the signal wiring line extended from the end of the coplanar waveguide and the ground wiring line is smaller than the spacing between the signal wiring line of the coplanar waveguide and the ground wiring line. | 05-10-2012 |
20120148263 | ARCHITECTURE OF AN OPTICAL REFUELING COMMUNICATION USING GLASS FIBER - A communication interface for communication between a storage tank and a refueling station is described. One embodiment of the communication interface includes a control unit; an optical transmitter comprising an IR-LED, the optical transmitter directly integrated into the control unit or mounted on the control unit; and an optical frontend optically connected to the optical transmitter. | 06-14-2012 |
20120170943 | Configuring optical launch powers in optical fiber transmission lines - A method includes transmitting optical signals through a heterogeneous sequence of spans of an all-optical transmission line. Each span has an optical transmission fiber connected to an optical amplifier. Each amplifier launches the signals into a sequential remainder of the line. The transmitting includes launching the optical signals into the highest loss fibers with substantially equal average optical launch powers or operating the spans with the highest loss fibers to have substantially equal quality products. The average optical launch powers are substantially equal to the inverse of a sum of (1−T | 07-05-2012 |
20120170944 | OPTICAL RECEIVER AND OPTICAL TRANSMITTER - There is provided an optical receiver. The optical receiver includes a board to be coupled with an optical transmission line array, an optical diode array disposed on the board, and the optical diode array including a plurality of photo diodes each of which receives light from a corresponding optical transmission line in the optical transmission array. Further bias suppliers, conversion circuits, and capacitors are provided on the board or a real side of the board. Each of the photo diodes includes a first electrode and second electrodes, the first electrode receives a bias voltage supplied by a bias supplier, a current signal flowing through the second electrode is converted by a conversion circuit into a voltage signal, and one end of a capacitor is coupled to the first electrode and the other is grounded. | 07-05-2012 |
20120195601 | OPTICAL TRANSMITTER WITH HYBRIDLY INTEGRATED DRIVER - An optical transmitter includes a transmitter optical subassembly (TOSA) having a transistor outline (TO) package, a flexible circuit, and at least one active electronic device mounted on the flexible circuit. The active electronic device includes circuitry for processing signals communicated to and from the TOSA. | 08-02-2012 |
20120243881 | Extended Temperature Fiber Optic Cable Design - A fiber optic cable for use in a downhole environment is disclosed. The fiber optic cable includes a tube having an interior region; an optical fiber disposed in the interior region of the tube; a gas in the interior region; and a gel in the interior region, wherein the gel is configured to reduce stress on the optical fiber in the presence of the gas at a temperature substantially near the flashpoint of the gel. One or more seals can be used to seal the gel and the inert gas in the interior region. In various aspects, the fiber optic cable can be used in a downhole environment. | 09-27-2012 |
20120275799 | ELECTRIC ENERGY STORAGE SYSTEM FOR A VEHICLE - An electric energy storage system for a vehicle, such as an electric or hybrid vehicle. The energy storage system has multiple electric components and data transmission devices for transmitting data signals between the electric components. Here, the data transmission devices include at least one transmission link for electromagnetic radiation to transmit data signals. | 11-01-2012 |
20130039664 | TENSILE STRAINED SEMICONDUCTOR PHOTON EMISSION AND DETECTION DEVICES AND INTEGRATED PHOTONICS SYSTEM - Tensile strained germanium is provided that can be sufficiently strained to provide a nearly direct band gap material or a direct band gap material. Compressively stressed or tensile stressed stressor materials in contact with germanium regions induce uniaxial or biaxial tensile strain in the germanium regions. Stressor materials may include silicon nitride or silicon germanium. The resulting strained germanium structure can be used to emit or detect photons including, for example, generating photons within a resonant cavity to provide a laser. | 02-14-2013 |
20130142521 | Electro-Optical Single-Sideband Modulator - An electro-optical single-sideband modulator comprising:
| 06-06-2013 |
20130148984 | MODULAR DEVICE FOR AN OPTICAL COMMUNICATION MODULE - A modular device for an optical communication module configured to be coupled to an optical transmission medium. The modular device may include a first edge and a second edge and N number of electrical circuit channels between the first and second edges. Each electrical circuit channel may include at least one element configured to provide functionality for communicating optical signals through the optical transmission medium. The modular device may also have a width between the first and second edges so that each of the N number of electrical circuit channels of C number of modular devices aligns with one of P number of interface channels of an opto-electrical interface configured to be coupled to the optical transmission medium when C equals P/N and C is a whole number greater than zero. | 06-13-2013 |
20130163997 | OPTICAL FIBER TRANSMISSION SYSTEM - An optical fiber transmission system includes a light emitting source, a plurality of light receiving terminals, and a plurality of optical fibers connecting the light emitting source to the light receiving terminals. The optical fiber transmission system further includes a plurality of controlling modules positioned between the light receiving terminals and the optical fibers. Each of the plurality of controlling modules includes a controller, a signal analyzer, and a reflective member. The signal analyzer and the reflective member are connected to the controller and analyze and reflect optical signals respectively. | 06-27-2013 |
20130195470 | OPTICAL MODULE, OPTICAL TRANSMISSION DEVICE AND METHOD OF MANUFACTURING OPTICAL TRANSMISSION DEVICE - An optical module includes a circuit board having flexibility, a photoelectric conversion element mounted on a mounting surface of the circuit board, a semiconductor circuit element mounted on the mounting surface of the circuit board and electrically connected to the photoelectric conversion element, a plate-shaped optical connection member having a groove into which an end part of an optical fiber is pushed so as to be housed and optically connecting the optical fiber and the photoelectric conversion element, and a supporting member arranged so as to sandwich the optical connection member between the circuit board. The groove is formed between the semiconductor circuit element and the supporting member so as to have an opening into which the optical fiber is pushed at the supporting member side. The semiconductor circuit element has a height from the mounting surface of the circuit board higher than the photoelectric conversion element. | 08-01-2013 |
20130223852 | Optical Communication Transmitting Device and Method of Manufacturing the same - An optical communication transmitting device includes a substrate, a first layer with a first optical refractive index formed on the substrate, a waveguide unit formed with a second optical refractive index formed on the first layer, and a second layer with a third optical refractive index covered on the top of the waveguide unit. The second optical refractive index is greater than the first optical refractive index. The second optical refractive index is greater than the third optical refractive index. The waveguide unit is formed from a photo-resistor layer by a high energy light source exposure. | 08-29-2013 |
20130302040 | OPTICAL-ELECTRICAL CONVERSION MODULE AND OPTICAL TRANSMISSION ASSEMBLY USING THE SAME - An optical transmission assembly includes a first optical-electrical conversion module, a second optical-electrical conversion module and a optical waveguide connecting the first and the second optical-electrical conversion modules for transmitting optical signals. The first optical-electrical conversion module and the second optical-electrical conversion module each includes a circuit board, an optical signal emitting member, an optical signal receiving member, and a cover. The optical signal emitting member and the optical signal receiving member are mounted on the circuit board. The circuit board defines a positioning groove. The cover includes a latching portion latching with the positioning groove. The cover defines a latching groove. The optical waveguide includes a inserting portion to latch with the latching groove. The present disclosure further provides an optical-electrical conversion module. | 11-14-2013 |
20130315608 | BIDIRECTIONAL AND DOUBLE-FREQUENCY OPTICAL TRANSMISSION MODULE AND TRANSMISSION ASSEMBLY - An optical transmission assembly includes a base plate, an optical signal emitting member, an efferent optical fiber, an optical coupler, an afferent optical fiber, and an optical signal receiving member. The optical signal emitting member is mounted on or besides the base plate. The optical signal isolator is mounted on the base plate, and alignes with the optical signal emitting member. The efferent optical fiber is mounted on the base plate. The optical coupler is located besides the base plate, coupling with the optical signal isolator via the efferent optical fiber. The afferent optical fiber is mounted on the base plate. The optical signal receiving member is mounted on or besides the base plate, coupling with the optical coupler via the afferent optical fiber. The present disclosure further includes a bidirectional and double-frequency optical transmission module having the optical transmission assembly. | 11-28-2013 |
20140016946 | Agile Light Source Provisioning for Information and Communications Technology Systems - A chassis includes a plurality of continuous wave lasers each operable to emit a continuous wave optical beam at the same power as the other lasers, and a plurality of optical couplers operable to input the continuous wave optical beams of the same power and output a plurality of continuous wave optical beams at different powers. The chassis further includes a plurality of optical assemblies operable to modulate the continuous wave optical beams of different powers into a plurality of modulated optical signals at different powers and couple the modulated optical signals onto different length optical mediums so that lower power ones of the modulated optical signals are coupled to shorter ones of the optical mediums and higher power ones of the modulated optical signals are coupled to longer ones of the optical mediums. | 01-16-2014 |
20140023380 | SURFACE EMITTING SEMICONDUCTOR LASER, SURFACE EMITTING SEMICONDUCTOR LASER DEVICE, OPTICAL TRANSMISSION DEVICE, AND INFORMATION PROCESSING APPARATUS - A surface emitting semiconductor laser includes: a substrate; a first semiconductor multilayer reflector on the substrate including laminated pairs of a high refractive index layer relatively high in refractive index and a low refractive index layer relatively low in refractive index; an active region on or above the first reflector; a second semiconductor multilayer reflector on or above the active region including laminated pairs of a high refractive index layer relatively high in refractive index and a low refractive index layer relatively low in refractive index; and a cavity extending region formed between the first reflector and the active region or between the second reflector and the active region, having an optical film thickness greater than an oscillation wavelength, extending a cavity length, including a conductive semiconductor material, and including an optical loss causing layer at at least one node of a standing wave of a selected longitudinal mode. | 01-23-2014 |
20140147129 | PHOTONIC INTEGRATED CIRCUIT FOR WAVELENGTH DIVISION MULTIPLEXING - In one embodiment, the optical transmitter is configured to generate a plurality of optical signals at a corresponding plurality of different wavelengths multiplexed onto an output waveguide. The transmitter includes a first and second converter including different first and second active materials configured to emit light at a first and a different second wavelength, respectively. Furthermore, the transmitter includes a first converter waveguide traversing the first and second material of the first and second converters. The second material is at an output end of the first converter waveguide and the first material is at an input end, upstream of the output end, of the first converter waveguide. The second active material is transparent to the light at the first wavelength and the output end of the first converter waveguide leads to the output waveguide. | 05-29-2014 |
20140153934 | OPTICAL MODULATOR AND OPTICAL TRANSMITTER - An optical modulator includes a Mach-Zehnder optical waveguide that includes a pair of parallel waveguides, and a two-input-one-output optical coupler that couples light output from the parallel waveguides; a branching waveguide that branches a portion of light output from the optical coupler; and a light receiving unit that receives the light output from the branching waveguide. Orientation of an output end of the branching waveguide is angled toward the light receiving unit, to be oblique with respect to the parallel waveguides, and orientation of an output end of the optical coupler is angled toward a side opposite to that of the output end of the branching waveguide, to be oblique with respect to the parallel waveguides. | 06-05-2014 |
20150050031 | Wireless Power Transmission Across a Rotating Interface - A method for enabling the transmission of power between two mutually rotating members without the use of wires or heavy inductive bundles has been invented in which the electrical signal is first converted an electro-magnetic wave, such as an optical or infrared beam, then transmit across the rotational interface using a fiber optic rotation joint, or similar device, and then finally converting that beam back into electrical power. | 02-19-2015 |
20150078763 | OPTICAL MODULE AND OPTICAL TRANSMITTER - An optical module includes a waveguide substrate including an optical waveguide and electrodes that apply electronic signals to the optical waveguide; a relay substrate disposed adjacent to the waveguide substrate; a terminal substrate disposed adjacent to the waveguide substrate and opposite to the relay substrate across the waveguide substrate; and a carrier substrate on which the waveguide substrate, the relay substrate, and the terminal substrate are mounted. The electrodes have a first interconnect unit from the relay substrate to the terminal substrate via the waveguide substrate and second interconnect units from the first interconnect unit and branching on the terminal substrate. Among the second interconnect units, a first interconnect branch includes a capacitor and a terminal resistor; and a second interconnect branch is connected to an interconnect of the carrier substrate via a bias resistor, passes under the waveguide substrate to a DC electrode for bias-adjusting on the relay substrate. | 03-19-2015 |
20150086219 | ENHANCED OPTICAL MODULATION USING SLOW LIGHT - A photonic integrated circuit (PIC) is described. This PIC includes a semiconductor-barrier layer-semiconductor diode in an optical waveguide that conveys an optical signal, where the barrier layer is an oxide or a high-k material. Moreover, semiconductor layers in the semiconductor-barrier layer-semiconductor diode may include geometric features (such as a periodic pattern of holes or trenches) that create a lattice-shifted photonic crystal optical waveguide having a group velocity of light that is lower than the group velocity of light in the first semiconductor layer and the second semiconductor layer without the geometric features. The optical waveguide is included in an optical modulator, such as a Mach-Zehnder interferometer (MZI). | 03-26-2015 |
20150086220 | Optical Communication Techniques - Techniques relating to optical communications are illustrated. In an example, a system for optical communications includes a laser emitting device including an emission surface for emission of a laser beam. An optical waveguide may be optically coupled to the laser emitting device to receive the laser beam from the laser emitting device. A fault photo-detector surrounds the emission surface. The fault photo-detector is to detect a portion of the laser beam accidentally back-reflected towards the laser emitting device. | 03-26-2015 |
20150132015 | OPTICAL RESONATOR APPARATUS, OPTICAL TRANSMITTER AND CONTROLLING METHOD FOR OPTICAL RESONATOR - An optical resonator apparatus includes an optical resonator unit wherein ring optical resonators each including a first optical waveguide and a resonance wavelength adjustment electrode are coupled in cascade connection and round-trip lengths of the ring optical waveguides are different from each other and vary in order from an input side to an output side, and a controller that adjusts a resonance wavelength of each ring optical resonator in order beginning with the ring optical resonator provided at the most input side so as to match with an input light wavelength and, when an inter-channel occurs, adjusts the resonance wavelength of the first ring optical resonator from the input side so as to match with a second-matching input light wavelength and adjusts the resonance wavelengths of the second and succeeding ring optical resonators from the input side so as to match with the first-matching input light wavelength. | 05-14-2015 |
20150293322 | CABLE, ELECTRONIC DEVICE, AND METHOD FOR CONTROLLING ELECTRONIC DEVICE - There is provided a cable including at least one optical fiber cable, at least two electrical cables provided so as to sandwich the optical fiber cable, and plugs positioned at both ends and each having an electrical contact part connected to each of the electrical cables. | 10-15-2015 |
20150303653 | OPTICAL DEVICE, OPTICAL TRANSMISSION DEVICE, OPTICAL RECEPTION DEVICE, HYBRID LASER AND OPTICAL TRANSMISSION APPARATUS - An optical device includes a silicon waveguide core having a tapered portion having a sectional size that decreases toward a terminal end portion thereof, a dielectric waveguide core contiguous to the silicon waveguide core while covering at least the tapered portion, the dielectric waveguide core having a refractive index lower than that of the silicon waveguide core and configuring a single-mode waveguide, and a diffraction grating provided at the single-mode waveguide and configuring a distributed Bragg reflection mirror. | 10-22-2015 |
20150318924 | OPTICAL TRANSMISSION MODULE AND IMAGING DEVICE - An optical transmission module includes: a photoelectric conversion element that converts an electrical signal to an optical signal; a photoelectric conversion element-driving IC that drives the photoelectric conversion element; an optical fiber that transmits the optical signal; a guide holding member that holds the optical fiber; a cable that supplies power to at least one of the photoelectric conversion element and the photoelectric conversion element-driving IC; and a substrate on which the photoelectric conversion element and the photoelectric conversion element-driving IC are mounted. The substrate has first and second planes which are perpendicular to each other. The photoelectric conversion element is mounted on the first plane. The optical fiber is connected to a back side of the first plane. An optical axis of the optical fiber is perpendicular to the first plane. The cable is connected to the second plane in parallel with the optical axis of the optical fiber. | 11-05-2015 |
20150333831 | ELECTRO-OPTICAL TRANSCEIVER DEVICE TO ENABLE CHIP-TO-CHIP INTERCONNECTION - An apparatus includes a substrate and a waveguide coupled to a surface of the substrate. The surface forms a cladding layer of the waveguide. The apparatus includes a photodetector optically coupled to an end of the waveguide. The photodetector is configured to output an electrical signal responsive to receiving a light signal from a core of the waveguide. The apparatus also includes an amplifier device coupled to the substrate. The amplifier device is electrically coupled to the photodetector to amplify the electrical signal to produce an amplified electrical signal. | 11-19-2015 |
20150333832 | Optical Transmission Module - Provided is an inexpensive and compact optical transmission module having high coupling efficiency between an optical fiber and a light projecting element and/or a light receiving element. This optical transmission module includes a lead frame including an electric wiring pattern formed therein, a resin housing formed through insert-molding of the lead frame, and an electric device mounted on the lead frame and including a light projecting element for photoelectric conversion. The lead frame forms a slit positioning an optical fiber to be coupled and a reflection mirror reflecting and condensing light from the light projecting element to the optical fiber. | 11-19-2015 |
20160064899 | SURFACE-EMITTING SEMICONDUCTOR LASER, SURFACE-EMITTING SEMICONDUCTOR LASER DEVICE, OPTICAL TRANSMISSION DEVICE, AND INFORMATION PROCESSING DEVICE - Provided is a surface-emitting semiconductor laser including a substrate; a first semiconductor multilayer reflector of a first conductivity type formed on the substrate, the first semiconductor multilayer reflector including plural pairs of a low-refractive-index layer and a high-refractive-index layer; a cavity region formed on the first semiconductor multilayer reflector; a second semiconductor multilayer reflector of a second conductivity type formed on the cavity region, the second semiconductor multilayer reflector including plural pairs of a low-refractive-index layer and a high-refractive-index layer; a columnar structure extending from the second semiconductor multilayer reflector to the cavity region; and a current confinement layer formed inside the columnar structure by selective oxidation of a semiconductor layer containing Al. The cavity region includes an active region; and a cavity extension region interposed between the active region and the first semiconductor multilayer reflector. | 03-03-2016 |
20160103282 | OPTICAL DEVICE USING ECHELLE GRATING THAT PROVIDES TOTAL INTERNAL REFLECTION OF LIGHT - Embodiments of the present disclosure are directed toward techniques and configurations for an optical device having a semiconductor layer to propagate light and a mirror disposed inside the semiconductor layer and having echelle grating reflective surface to substantially totally internally reflect the propagating light inputted by one or more input waveguides, to be received by one or more output waveguides. The waveguides may be disposed in the semiconductor layer under a determined angle relative to the mirror reflective surface. The determined angle may be equal to or greater than a total internal reflection angle corresponding to the interface, to provide substantially total internal reflection of light by the mirror. The mirror may be formed by an interface of the semiconductor layer comprising the mirror reflective surface and another medium filling the mirror, such as a dielectric. Other embodiments may be described and/or claimed. | 04-14-2016 |
20160112131 | Optical Relay Cable - Described herein is a system for transmitting an optical signal from a first location to a second location. The system may include first and second mounting fixtures, a reception module, an optical fiber, and a transmission module. The first fixture may define at least a first cavity and a first aperture at the bottom of the cavity. The reception module may be disposed in the cavity, and include a reflector for receiving the optical signal from a first direction through the first aperture and redirecting the optical signal in another direction. The optical fiber may be for receiving the optical signal from the reflector. The second fixture may define at least a second cavity and a second aperture on the side of the cavity. The transmission module may be disposed in the second cavity and direct the optical signal from the optical fiber through the second aperture. | 04-21-2016 |
20160149646 | OPTICAL DEVICES INCLUDING A HIGH CONTRAST GRATING LENS - Techniques related to optical devices including a high contrast grating (HCG) lens are described herein. In an example, an optical device includes a transparent substrate. A laser emitter or detector at a first side of the transparent substrate to emit or detect a laser light transmitted via the transparent substrate. A HCG lens is at a second side of the transparent substrate to transmit and refract the laser light. | 05-26-2016 |
20160380701 | QUASI-OPTICAL COUPLER - A quasi-optical coupling system launches and extracts surface wave communication transmissions from a wire. At millimeter-wave frequencies, where the wavelength is small compared to the macroscopic size of the equipment, the millimeter-wave transmissions can be transported from one place to another and diverted via lenses and reflectors, much like visible light. Transmitters and receivers can be positioned near telephone and power lines and reflectors placed on or near the cables can reflect transmissions onto or off of the cables. The lenses on the transmitters are focused, and the reflectors positioned such that the reflected transmissions are guided waves on the surface of the cables. The reflectors can be polarization sensitive, where one or more of a set of guided wave modes can be reflected off the wire based on the polarization of the guided wave modes and polarization and orientation of the reflector. | 12-29-2016 |