Class / Patent application number | Description | Number of patent applications / Date published |
398212000 | Including optical element (e.g., lens, mirror, etc.) | 45 |
20080219680 | OPTICAL RECEIVING APPARATUS AND BALANCE ADJUSTMENT METHOD - Disclosed is a optical receiving apparatus including a balanced receiver comprising first and second light receiving elements which receive respective optical signals from first and second ports of a 1-bit delay interferometer, monitor units that monitor amplitudes and delays at the first and second light receiving elements, respectively, control units that variably respectively control attenuations and delays on the paths between the first and second output ports of the 1-bit delay interferometer and the first and second light receiving elements, based on monitored results by the monitor units. | 09-11-2008 |
20080232824 | Optical Receiver Scheme with All-Optical Decision Element - A receiver scheme ( | 09-25-2008 |
20080298817 | Light Receiving Device - A light receiving device includes a frame | 12-04-2008 |
20080298818 | Optical Receiver 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 |
20090097867 | OPTICAL RECEIVER USING MACH-ZEHNDER INTERFEROMETER - The present invention relates to an optical receiver, in which the transmittance of a Mach-Zehnder interferometer can be locked at a normal operation point in a simple structure and control. | 04-16-2009 |
20090269083 | SPACE DIVERSITY RECEIVER FOR OPTICAL COMMUNICATIONS - An optical beam combiner is provided, which allows efficient collection of light for various applications: non-line of sight and free-space optical communications, remote sensing, optical imaging and others. A multitude of transverse scattered optical beam portions is captured by the multi-aperture array positioned perpendicular to the beam projection direction. These beam portions are combined first into a single optical waveguide with modulating the beam portions phase and coupling ratio of directional couplers in the optical beam combiner tuned to maximize the final output power. A portion of the output beam is used for the power detection and forming a feedback signal for the phases and coupling ratios adjustment. The data is recovered from the received optical beam using coherent detection. | 10-29-2009 |
20100054761 | Monolithic coherent optical detectors - An optical receiver has a monolithically integrated electrical and optical circuit that includes a substrate with a planar surface. Along the planar surface, the monolithically integrated electrical and optical circuit has an optical hybrid, one or more variable optical attenuators, and photodetectors. The optical hybrid is connected to receive light beams, to interfere light of said received light beams with a plurality of relative phases and to output said interfered light via optical outputs thereof. Each of the one or more variable optical attenuators connects between a corresponding one of the optical outputs and a corresponding one of the photodetectors. | 03-04-2010 |
20100129089 | DEMODULATOR AND RECEIVING DEVICE - A demodulator includes: a splitter that branches a differential phase shift keying optical signal into a first branched optical signal passing through a first optical path and a second branched optical signal passing through a second optical path; a multiplexer that multiplexes the first branched optical signal having passed through the first optical path and the second branched optical signal having passed through the second optical path and makes interference between the first branched optical signal and the second branched optical signal; and a double refraction medium that reduces difference between phase differences between each polarized wave between the first branched optical signal and the second branched optical signal multiplexed by the multiplexer. | 05-27-2010 |
20100158542 | Detector module - A detector module for the reception of optical signals (SE) including a module housing having at least one electrical and at least one optical bushing, at least one electrical assembly connected to the electrical bushing, and at least one optical assembly connected to the optical bushing, the electrical and optical assemblies being arranged within the module housing, the optical and electrical assemblies being connected to one another via at least one optical interface, and the electrical assembly having at least one photodiode for converting the optical output signals of the optical assembly into electrical signals. The optical assembly has at least one collimator and on the output side transmits at least one beam comprising collimated electromagnetic rays running parallel to one another via a free-radiating connection as optical interface to the electrical assembly, and the electrical assembly receives the beam from the optical assembly via the free-radiating connection. | 06-24-2010 |
20100284703 | LIGHT RECEIVING CIRCUIT AND SIGNAL PROCESSING METHOD - A light receiving circuit includes: a 1-bit delay interferometer; two photodiodes; and a demodulating circuit for converting current signals of the photodiodes into voltages to thereby demodulate signals that have been modulated by return-to-zero differential phase shift keying, the demodulating circuit including a differential transimpedance amplifier, in which the differential transimpedance amplifier includes a level adjusting circuit that has a function of adjusting levels of a positive phase signal and a negative phase signal of two feedback closed loops. | 11-11-2010 |
20100303475 | RECEIVER OF MULTIMEDIA DATA - Disclosed is a multimedia data receiver using an optical cable that can receive multimedia data such as an image, voice and control signal whose media are different from each other through an optical transmission medium such as plastic or glass optical cables in a short or long distance area. The multimedia data receiver includes: an optical driver, amplifying a received signal of a single transmission format that is optical-to-electrical converted by an optical module connected to an optical cable, converting a serial data for transmission into an analog signal, performing optical transmission through the optical module; an interface control logic, extracting a control signal from the signal received through the optical driver, interfacing control data; and a digital signal processing logic, converting the signal received through the optical driver into data of the original transmission format through converting the signal into a digital signal and decoding the digital signal, deserializing a serial image data, transmitting the data to a display device connected thereto. | 12-02-2010 |
20100303476 | MONOLITHIC WIDELY-TUNABLE COHERENT RECEIVER - Various embodiments of a coherent receiver including a widely tunable local oscillator laser are described herein. In some embodiments, the coherent receiver can be integrated with waveguides, optical splitters and detectors to form a monolithic optical hetero/homodyne receiver. In some embodiments, the coherent receiver can demodulate the full phase information in two polarizations of a received optical signal over a range of optical wavelengths. | 12-02-2010 |
20110008062 | METHOD AND APPARATUS FOR COMMUNICATION IN AN ILLUMINATION SYSTEM USING A LIQUID LENS - A method and apparatus for communicating information content by modulation of light in an illumination system via a liquid lens optically coupled to the illumination system and capable of modulation of light thereof, using resonant modes of the liquid lens. A modulation control system operatively coupled to the liquid lens and to the information content is configured to represent at least a portion of the information content as a time-varying configuration of the liquid lens, the time-varying configuration substantially including one or more of said one or more resonance modes. A receiver system optically coupled to the liquid lens is configured to reconstruct at least a portion of the information content from light modulated by the time-varying configuration of the liquid lens. | 01-13-2011 |
20110129236 | OPTICAL DEVICE, OPTICAL HYBRID CIRCUIT, AND OPTICAL RECEIVER - According to aspects of embodiments, an optical device includes a first coupler configured to split an optical signal; a second coupler configured to cause optical signals to interfere with each other, a first waveguide configured to couple the first coupler to the second coupler, the first waveguide includes a first phase shifter region having a section narrower in width than an end of the first phase shifter region, the second waveguide includes a second phase shifter region having a section wider in width than an end of the second phase shifter region. | 06-02-2011 |
20120076509 | RECEIVER CHIP AND METHOD FOR ON-CHIP MULTI-NODE VISIBLE LIGHT COMMUNICATION - A receiver chip, system and method for on-chip multi-node visible light communication, the receiver chip comprising: an array of receiver cells comprising an array of photodetectors, each receiver cell comprises at least one photodetector and is to receive light through the at least one photodetector, and a logical layer for independently configuring at least one selected receiver cell as a communication receiving channel. The system comprises an array of receiver cells comprising an array of photodetectors, each receiver cell includes at least one photodetector and is to receive light through the at least one photodetector, a logical layer to independently configure at least one selected receiver cell as a communication receiving channel, and a processor to receive data from the logical layer and control the logical layer for configuration of the receiver cells. | 03-29-2012 |
20120099872 | OPTICAL COMMUNICATION MODULE - Plural conductive plates extend from a transparent containing unit containing the photoelectric conversion device, plural electrical circuit components are connected to the conductive plate, and the conductive plate extending from the transparent containing unit is accommodated in a housing while the conductive plate is bent. At that time, the conductive plate extending from the transparent containing unit is coupled at two portions in an extending direction by coupled-fixing members made of non-conductive synthetic resin, the electrical circuit components are mounted between the coupled-fixing members and the conductive plate is bent at portions outside these two coupled-fixing members. In the case that the conductive plate must be cut to generate a floating point portion, a floating-point fixing member is provided for coupling and fixing the floating point portion to an adjacent conductive plate. | 04-26-2012 |
20120301158 | Optical Receiver - An optical receiver includes interference means | 11-29-2012 |
20130148985 | MONOLITHIC WIDELY-TUNABLE COHERENT RECEIVER - Various embodiments of a coherent receiver including a widely tunable local oscillator laser are described herein. In some embodiments, the coherent receiver can be integrated with waveguides, optical splitters and detectors to form a monolithic optical hetero/homodyne receiver. In some embodiments, the coherent receiver can demodulate the full phase information in two polarizations of a received optical signal over a range of optical wavelengths. | 06-13-2013 |
20130170843 | OPTICAL COHERENT RECEIVER WITH LOCAL OSCILLATOR LASER HAVING HYBRID CAVITY - A coherent optical receiver includes a local oscillator (LO) laser configured to provide an LO signal. The LO laser includes a hybrid external cavity and an active gain medium within the hybrid external cavity, where the LO laser is defined between a first optical reflector on a chip including the active gain medium and a second optical reflector not on the chip. | 07-04-2013 |
20130279920 | REPEATABLY ALIGNABLE FIBER OPTIC CONNECTOR - A fiber optic cable and connector includes a bundle of optical fibers and a ferrule associated with the bundle. The ferrule has an insertable portion and an external portion, the insertable portion retaining the respective proximal ends of the optical fibers on substantially the same plane with one another, the plane being substantially perpendicular to the longitudinal access of the ferrule. A collar around the external portion of the ferrule has a positioning means with a slot, a recess, a hole, a tongue, a pin, a shaft, a bar, a notch, a flat, a detent, a bump, a ridge or a groove. The positioning means engages with at least one positioning element, and provides a repeatable rotational alignment of the fibers with respect to a receiver when engaged with the positioning element. An engagement surface engages with the receiver such that, when so engaged with pressure in a direction normal to the longitudinal axis of the ferrule and towards the receiver, the engagement surface prevents substantial movement of the longitudinal axis of the ferrule with respect to the receiver. A securing sleeve moveably encircles a portion of the fiber optic bundle and has a fastener for secure connection with the receiver. The securing sleeve has a pressure surface for engaging the collar and applying pressure on the collar in a direction normal to the longitudinal axis of the ferrule and toward the receiver. | 10-24-2013 |
20130302042 | OPTICAL RECEIVER - An optical receiver is provided with a photoelectric converter that outputs an electrical signal according to light that is received by a light-receiving region. The optical receiver is provided with a condensing lens and optical filter that are located in an optical path from where signal light enters towards the light-receiving region. The condensing lens condenses the signal light onto the light-receiving region. The optical filter reflects light having a first wavelength that is included in the signal light using a front surface thereof and reflects light having a second wavelength that is included in the signal light using a rear surface thereof that faces the front surface so that the light is emitted through the front surface. | 11-14-2013 |
20140016948 | OPTICAL RECEIVER - Provided is an optical receiver including a first delay interferometer, a second delay interferometer, and an input light splitting portion for inputting modulated light. The first delay interferometer includes a first light splitting portion for splitting the input light into first light and second light, a first reflecting portion and a second reflecting portion for causing the first light and the second light to return to the first light splitting portion. The second delay interferometer includes a second light splitting portion for splitting the input light into third light and fourth light, a third reflecting portion and a fourth reflecting portion for causing the third light and the fourth light to return to the second light splitting portion. A region between the first light splitting portion and the second reflecting portion intersects with a region between the second light splitting portion and the fourth reflecting portion. | 01-16-2014 |
20140016949 | OPTICAL SIGNAL DETECTION CIRCUIT AND OPTICAL RECEIVER - An optical signal detection circuit ( | 01-16-2014 |
20140133871 | OPTICAL RECEIVER MODULE - An optical receiver module capable of increasing the range in which the error in distance between a collecting lens and a light receiving section is allowed is provided. In the optical receiver module according to the invention, the optical receiver includes a semiconductor substrate to which the light from the collecting lens is input, and through which the light passes, and a light receiving section disposed on a side (a reverse side) of the semiconductor substrate, the side being further from the collecting lens, and adapted to receive the light transmitted through the semiconductor substrate, and then convert the light into an electrical signal. On a side (an obverse side) of the semiconductor substrate, the side being nearer to the collecting lens, there is formed a lens surface adapted to converge light from the collecting lens toward the light receiving section. | 05-15-2014 |
20140193165 | ELECTRONIC ALIGNMENT OF OPTICAL SIGNALS - Embodiments of the invention are generally directed to electronic alignment of optical signals. An embodiment of an apparatus includes an array of photo sensors; a bus coupled with the array, the bus including detection circuitry for each photo sensor to generate a signal in response to the photo sensor receiving an optical signal; and a processing component to process a group of signals, the group of signals being signals generated by the detection circuitry for a subset of the photo sensors in response to the photo sensors receiving the optical signal, to generate an output signal. | 07-10-2014 |
20140270811 | MULTI-CHANNEL OPTICAL RECEIVING MODULE - A multi-channel optical receiving module includes a first substrate disposed on a bench, optical fibers disposed in grooves of the first substrate, a first lens disposed on the first substrate and collimating optical signals through the optical fibers, a second substrate disposed on the bench at a side of the first substrate, a light receiving device disposed on the second substrate, a second lens disposed over the light receiving device, a mirror reflecting the optical signals between the first lens and the second lens, and a block fixing the mirror. The block includes through-holes transmitting the optical signals between the first and second lenses without refraction of the optical signals. | 09-18-2014 |
20140334832 | Method And System For A Narrowband, Non-Linear Optoelectronic Receiver - Methods and systems for a narrowband, non-linear optoelectronic receiver are disclosed and may include amplifying a received signal, limiting a bandwidth of the received signal, and restoring the signal utilizing a level restorer, which may include a non-return to zero (NRZ) level restorer comprising two parallel inverters, with one being a feedback path for the other. The inverters may be single-ended or differential. A photogenerated signal may be amplified in the receiver utilizing a transimpedance amplifier and programmable gain amplifiers (PGAs). A received electrical signal may be amplified via PGAs. The bandwidth of the received signal may be limited utilizing one or more of: a low pass filter, a bandpass filter, a high pass filter, a differentiator, or a series capacitance on the chip. The signal may be received from a photodiode integrated on the chip, where the photodiode may be AC coupled to an amplifier for the amplifying. | 11-13-2014 |
20140348516 | MONOLITHIC WIDELY-TUNABLE COHERENT RECEIVER - Various embodiments of a coherent receiver including a widely tunable local oscillator laser are described herein. In some embodiments, the coherent receiver can be integrated with waveguides, optical splitters and detectors to form a monolithic optical hetero/homodyne receiver. In some embodiments, the coherent receiver can demodulate the full phase information in two polarizations of a received optical signal over a range of optical wavelengths. | 11-27-2014 |
20140376928 | EXTERNAL LIGHT GUIDE FOR ELECTRONIC DEVICES - The present invention is directed, in part, to a receiver for an infrared light source. The receiver comprises a substantially transparent body; a sensor for receiving infrared light; and a substantially planar first surface on the transparent body. The first surface is configured to direct light from the infrared light source to the sensor. The substantially planar first surface comprises the end of the substantially transparent body. The substantially planar first surface provides an internally reflective surface that directs light into the interior of the substantially transparent body so it will make contact with the sensor. | 12-25-2014 |
20140376929 | OPTICAL RECEIVER AND OPTICAL AXIS ALIGNMENT METHOD THEREOF - An optical receiver comprises a package provided with an input window; a polarization-maintaining optical fiber fixable to the input window; a polarization beam splitter, disposed on the package, for inputting light outputted from the polarization-maintaining optical fiber and outputting first output light and second output light having respective polarization directions different from each other; a beam splitter, disposed on the package, for splitting the first output light; a first light-receiving element, optically coupled to the beam splitter, having two light-receiving parts corresponding to two kinds of the output light split by the beam splitter; and a second light-receiving element, disposed on the package, for receiving the second output light. | 12-25-2014 |
20140376930 | OPTICAL RECEIVER AND METHOD FOR CONTROLLING OPTICAL RECEIVEROPTICAL RECEIVER, METHOD FOR CONTROLLING OPTICAL RECEIVER, AND METHOD FOR RECEIVING LIGHT - In an optical receiver which is compatible with a plurality of signal channels, it is difficult to receive signals properly because a variation in receiving light sensitivity of a photoelectric conversion unit occurs between a plurality of signal channels, therefore, an optical receiver according to an exemplary aspect of the invention includes an optical processing circuit processing input signal light to have been input and outputting a plurality of output signal light beams; and a plurality of photoelectric conversion means for receiving the plurality of output signal light beams respectively and outputting electric signals, wherein the photoelectric conversion means includes an avalanche photodiode which can control a multiplication factor of an output current as the electric signal by means of an applied voltage; and the avalanche photodiode operates with a driving voltage by which the output currents in the plurality of photoelectric conversion means become almost the same. | 12-25-2014 |
20150063831 | BURST MODE OPTICAL RECEIVER AND MEMORY SYSTEM USING THE SAME - A burst mode optical receiver includes a pre-amplifier configured to convert an optical burst mode signal into a voltage signal, a reference controller configured to determine a reference voltage for the voltage signal in response to a mode signal from a host indicating an interval during which the voltage signal is DC balanced, and a main amplifier configured to restore the voltage signal to a data signal based on the reference voltage. Related methods of operation are also discussed. | 03-05-2015 |
20150104199 | TUNABLE OPTICAL FILTER, TUNABLE OPTICAL COMPONENT, AND MULTI-WAVELENGTH PASSIVE OPTICAL NETWORK SYSTEM - The present application provides a tunable optical filter, including: a substrate, a tunable filter unit, a temperature control unit, and an enclosure, where: the substrate, the tunable filter unit, and the temperature control unit are placed inside the enclosure, where the enclosure includes a light incidence window and a light emergence window; the substrate is disposed adjacent to the light incidence window or the light emergence window, and configured to support the tunable filter unit; the temperature control unit is disposed on a surface of the tunable filter unit, and configured to adjust a channel wavelength of the tunable filter unit by means of temperature control; and optical paths of the light incidence window, the tunable filter unit and the light emergence window are aligned. The present application further provides an optical receive component, an optical transceiver component, and a multi-wavelength passive optical network system. | 04-16-2015 |
20150295659 | OPTICAL RECEIVER, STATION-SIDE OPTICAL NETWORK UNIT, AND LIGHT RECEPTION LEVEL MONITORING METHOD - An optical receiver includes a light receiving element configured to convert an input light signal into an electric current, a current mirror circuit including a reference current side transistor and a mirror current side transistor, the transistor being connected to the light receiving element, a current-voltage conversion circuit configured to convert an output current from the transistor into a voltage and output the voltage as a light reception level monitor voltage of the light receiving element, and a current sink circuit connected to the transistor and configured to feed an electric current to the transistor. | 10-15-2015 |
20150304053 | Compact Multiple Channel Optical Receiver Assembly Package - An optical assembly package is provided for the optical receive components of an optical transceiver. The optical assembly package includes a receptacle subassembly configured to receive an end of an optical fiber. A housing is provided having an opening at one end configured to receive the receptacle assembly. Optical routing and wavelength demultiplexing elements are mounted to a bottom wall of the housing. An electrical subassembly comprising a support plate, a circuit board mounted on the support plate, an integrated circuit mounted to the circuit board, and a plurality of photodetectors mounted to the support plate proximate an edge of the circuit board. The electrical subassembly is positioned a stacked arrangement beneath the housing to minimize an overall length of the optical assembly package. | 10-22-2015 |
20150311871 | RECEIVER CIRCUIT - A receiver circuit includes a first amplifier circuit to differentially amplify differential input signals by a linear operation, a second amplifier circuit configured to differentially amplify output differential signals of the first amplifier circuit by a limiting operation, a feedback circuit, first and second resistors coupled between the feedback circuit and outputs of the first amplifier circuit, and third and fourth resistors coupled between the feedback circuit and outputs of the second amplifier circuit. The feedback circuit amplifies a positive-phase signal that is output from a positive-phase output node thereof coupled to the first and third resistors, and a negative-phase signal that is output from a negative-phase output node thereof coupled to the second and fourth resistors, and feeds back a feedback signal after amplification to the first amplifier circuit. | 10-29-2015 |
20150311982 | DEVICES AND TECHNIQUES FOR INTEGRATED OPTICAL DATA COMMUNICATION - Devices and techniques for integrated optical data communication. An optical receiver may include a photodetector and a differential amplifier. The photodetector is coupled to an optical waveguide. The optical waveguide is configured to provide an optical signal encoding data. A first terminal of the differential amplifier is coupled to receive a photodetection signal from the photodetector. A second terminal of the differential amplifier is coupled to receive, from a noise measurement unit, a reference signal representing a noise component of the photodetection signal. The differential amplifier is configured to provide an amplifier signal encoding at least some of the data. | 10-29-2015 |
20160056899 | LED OPTICAL COMMUNICATION RECEIVING LENS AND LED OPTICAL COMMUNICATION SYSTEM - A LED optical communication receiving lens includes a first surface and a second surface opposite to the first surface. The first surface includes a first spherical surface and a second spherical surface connected to the first spherical surface. The second surface includes a third spherical surface and a planar surface connected to the third spherical surface. A position of the LED optical communication receiving lens is defined as a three-dimensional Cartesian coordinate system (x, y, z). Sphere centers and symmetric central points of the first spherical surface, the second spherical surface, and the third spherical surface are located on the x axis. The first spherical surface and the planar surface are transmitted surfaces. The second spherical surface and the third spherical surface are reflective surfaces. The present application also relates to a LED optical communication system including the LED optical communication receiving lens. | 02-25-2016 |
20160161683 | DYNAMIC RANGE ALIGNMENT TOLERANT OPTICAL COUPLING FOR FIBER OPTIC COMMUNICATIONS - In one exemplary embodiment, an optical coupler of a fiber optic system can include a light-source input cavity packaged in a outer casing. The cavity can receive an optical signal from a light source. An optical collimator packaged in the outer casing such that a receiving end of the optical collimator can receive the light source from the light-source input cavity. The optical collimator can include at least one beam forming stage. The optical collimator can generate a collimated beam output from the optical signal. An optical cavity can receive the collimated beam output of the optical collimator. The optical cavity can be coaxially included in a receiving optical fiber coupled with the outer casing coupled with optical cavity. The optical cavity can receive the collimated beam output of the optical collimator and input the collimated beam into the receiving optical fiber. | 06-09-2016 |
20160254867 | IMPACT IONIZATION DEVICES UNDER DYNAMIC ELECTRIC FIELDS | 09-01-2016 |
20170237504 | OPTICAL RECEIVER AND OPTICAL AXIS ALIGNMENT METHOD THEREOF | 08-17-2017 |
20190149245 | SYSTEMS AND METHODS FOR COHERENT OPTICS INTERFACE | 05-16-2019 |
398213000 | Having feedback | 3 |
20080292326 | Optical Voltage Controlled Oscillator for an Optical Phase Locked Loop - An optical phase locked loop ( | 11-27-2008 |
20100028023 | OPTICAL RECEIVER - There is provided an optical receiver capable of coping with a balanced optical input, and having neither the need for adjustment of the reference voltage for single-differential conversion, nor the need for a large-capacitance capacitor corresponding to a wideband signal, for connecting the output of the trans-impedance amp to the input of the limiter amp. The optical receiver comprises a balanced photodiode composed of two units of light-sensitive elements connected in series in the direction of an identical polarity, having a bidirectional current, a differential amplifier comprising differential input pair-transistors, an emitter follower section for causing respective output signals of the differential amplifier to undergo level shift, feedback resistance for feeding back output signals of the emitter follower section to respective input terminals of the differential amplifier, and a capacitor coupled to the base of the other transistor of the differential input pair-transistors. | 02-04-2010 |
20130216241 | OPTICAL RECEIVER USING INFINITE IMPULSE RESPONSE DECISION FEEDBACK EQUALIZATION - A technique is provided for configuring an optical receiver. A photo detector is connected to a load resistor, and the photo detector includes an internal capacitance. A current source is connected through a switching circuit to the load resistor and to the photo detector. The current source is configured to discharge the internal capacitance of the photo detector. The switching circuit is configured to connect the current source to the internal capacitance based on a previous data bit. | 08-22-2013 |