Abstract: An optical sub-assembly module and a cap thereof are provided. Two opposite ends of the cap are respectively defined as a light source end and a connecting end. The cap includes a receiving groove, a longitudinal groove, a lens structure and a plurality of pillar structures. The receiving groove is recessed inwardly from the light source end. The longitudinal groove is recessed inwardly from the connecting end. The lens structure is integrally formed with the cap, the lens structure is located between the receiving groove and the longitudinal groove, and the lens structure blocks spatial communication between the receiving groove and the longitudinal groove. Each of the pillar structures is connected to an inner wall that surrounds the receiving groove.

Abstract: A housing for an optical assembly includes a base and at least one finger. The base includes a hole configured to pass light to or from an electronic component. The finger is bent at an angle with respect to the base for securing the optical assembly within the housing. The base and the finger comprise a single monolithic structure of a sheet material.

Abstract: A surgical instrument includes a body assembly, a waveguide, a transducer, and a coupling assembly. In some versions the coupling assembly translates the transducer to couple the transducer to the waveguide. For instance, a gear having arcuate troughs may engage pins on the transducer and/or waveguide to mate the transducer to waveguide. A pawl may selectively engage and prevent rotation of the gear. Alternatively, lever arms may cam the transducer into the waveguide. The lever arms may selectively couple to a casing to prevent decoupling of the transducer and waveguide. In another configuration, a locking tab can be slid and locked into a slot to couple the transducer and waveguide. Further still, levers with self-locking pins may engage and couple the transducer to the waveguide. In another version, a rotatable body portion may engage a tab on the transducer to rotate and couple the transducer to the waveguide.

Abstract: A ceramic conversion element, a light-emitting device and a method for producing a ceramic conversion element are disclosed. In an embodiment a ceramic conversion element includes a central region with a structured top surface including a plurality of structure elements and a frame surrounding the central region, the frame having a planar top surface, wherein the central region and the frame are formed as one piece, and wherein the ceramic conversion element is configured to convert primary radiation into secondary radiation of a different wavelength range.

Abstract: The present disclosure provides pluggable optical modules that are prevented from reaching potentially dangerous temperatures when a fiber optic connector is not present and engaged with the associated module housing. Further, the present disclosure provides fiber optic connectors and/or pluggable optical modules that incorporate a port heat shield external to the associated face plate when the pluggable optical modules and fiber optic connectors are engaged, thereby preventing a user from contacting potentially hot and dangerous metallic surfaces of the module housings, as well as providing access for cooling air flow. The solutions presented herein are equally applicable to fixed optical ports and connectors as well.

Abstract: According to one embodiment, a via holds an optical fiber and has an opening in at least a first surface of a silicon substrate. An interconnect is provided at a second surface of the silicon substrate and connected to an optical semiconductor element. Side-surface electrodes are provided at a third surface of the silicon substrate. The third surface is other than the first surface and the second surface of the silicon substrate. At least a portion of the side-surface electrodes is connected to the interconnect. At least a portion of the side-surface electrodes have different lengths along the third surface.

Abstract: An optical collimating unit is provided that comprises a laser unit, and a lens having three optical surfaces, being a first refractive surface, a second reflective surface and a third refractive surface. Also provided is a light projection device comprising an optical collimating unit that comprises a laser unit, a lens and an optical component configured to shape laser beams being emitted into respective desired light patterns.

Abstract: A semiconductor device package includes: (1) a substrate having a first surface; (2) a waveguide disposed in the substrate; and (3) an optical device including: (a) a first portion extending into the substrate and not extending beyond the first surface of the substrate, and (b) a second portion extending along the first surface of the substrate, wherein the second portion of the optical device comprises a protrusion and the substrate defines a groove extending from the first surface of the substrate, and wherein the protrusion of the second portion of the optical device engages with the groove of the substrate.

Abstract: An optical transmission module includes: an optical fiber a cross section of which has a circular shape and an end surface of which is an inclined surface; and an optical element part including an optical element, wherein a cutout surface extending in an optical axis direction is formed in an outer circumference of an end portion of the optical fiber, and the angle of the inclined surface with respect to the main surface of the optical element is defined by the cutout surface, such that light guided through the optical fiber is optically coupled to the optical element.

Abstract: The present disclosure relates to an electronic device. The electronic device can include a device body, a control main board, and at least one function module mounted in the device body. The control main board of the electronic device is provided with a pad group and a flexible printed circuit board, such that each pad group is electrically connected to the corresponding function module by the flexible printed circuit board. The first connecting terminal of the flexible printed circuit board is electrically connected to the function module, and the pins of the second connecting terminal of the flexible printed circuit board correspond to and electrically cooperate with the pads of the pad group.

Abstract: Embodiments of the present disclosure relates to an optical module, including a bracket, and a handle and a plate both of which are connected to the bracket, where the plate is rotationally connected to the bracket, and a first end of the plate is provided with a buckle, and a second end of the plate abuts against a driving portion disposed on the handle, the driving portion is configured to: while the handle is moving along a length direction of the bracket, drive the second end of the plate that abuts against the driving portion to move, resulting in rotation of the buckle provided at the first end of the plate. On this basis, a lateral unlocking of the optical module is achieved along its length direction with a high unlocking reliability.

Abstract: An optical module includes a plurality of ports configured to connect to a multi-fiber cable that includes transmit fibers and receive fibers therein for the plurality of ports; a detector for each of the plurality of ports configured to detect loss of signal at a port level; and a processor configured to perform automatic power reduction only for affected ports of the multi-fiber cable that have a detected loss of signal. The multi-fiber cable can be an MPO cable.

Abstract: A angle detection system, includes a first member pivotally coupled to a second member. An optical cable connecting an optical transmitter provided on the first member and an optical receiver provided on the second member is used by an angle detection engine to determine signal loss of an optical signal provided by the optical transmitter through the optical cable to the optical receiver. The angle detection engine then determines, based on the signal loss, a first angle of the second member relative to the first member. The angle detection engine then performs an instruction based on the first angle.

Abstract: A host board for mounting an optical transceiver includes a connector that is configured to attach thereto and detach therefrom an optical transceiver having at least one lane and includes electrical contacts as many as the at least one lane, a management unit configured to receive lane information regarding the at least one lane of the optical transceiver from the optical transceiver through the connector and specify an available electrical contact, and a communication unit configured to communicate with the optical transceiver through the connector. The communication unit is configured to communicate information with the optical transceiver through the electrical contact specified by the management unit.

Abstract: An optical subassembly includes a receptacle, a ferrule and a ferrule fastening component. The ferrule and the ferrule fastening component are connected with the receptacle. The ferrule fastening component includes a fastening portion and a blocking portion connected with each other. The fastening portion is fastened with the receptacle, and the blocking portion touches the ferrule.

Abstract: A socket (2) for a headphone set, comprising: four terminals (5, 6, 7, 8), arranged to contact with terminal contacts (11a, 12a, 13, 14a) of a plug of a headphone set, the terminals longitudinally spaced within a plug-receiving space of the socket, wherein two of the adjacent terminals are electrically connected together.

Abstract: A tunable filter device includes a wavelength dependent splitter; a tuning element that tunes a characteristic wavelength of the wavelength dependent splitter to a wavelength of an optical signal; and a first optical coupler that splits the optical signal into an input optical signal input to the wavelength dependent splitter and a reference optical signal, where a first output outputs a band stop filtered portion and a second output outputs a band pass filtered portion of the input optical signal. The device further includes a second optical coupler that combines the reference optical signal with the band stopped filtered portion to provide a coupled optical signal; a photodiode that provides at a photocurrent indicating a difference between the wavelength of the optical signal and the characteristic wavelength; and a control loop that provides a control signal for automatically tuning the characteristic wavelength based at least in part on the photocurrent.

Abstract: A method includes obtaining a Photonic Integrated Circuit (PIC) with a butt-joint between a first core and a second core, wherein the butt-joint includes a poor quality region, wherein the first core is associated with a first optical device and the second core is associated with a second optical device, and wherein the first optical device and the second optical device are each on the PIC; etching away at least part of the poor quality region to form an etch trench between the first core and the second core; and growing an interconnect core between the first core and the second core in the etch trench.

Abstract: A modulator and a capacitor are integrated on a semiconductor substrate for modulating a laser beam. Integrating the capacitor on the substrate reduces parasitic inductance for high-speed optical communication.

Abstract: To provide an optical subassembly, an optical module, and an optical transmission equipment including simpler components. A first component with an optical semiconductor device mounted thereon that dissipates heat generated by the optical semiconductor device to outside, a second component in contact with the first component to form a box type housing, and a receptacle terminal that optically joined to the optical semiconductor device are provided, wherein the second component includes a window structure for transmitting light transmitted between the optical semiconductor device and the receptacle terminal, and the receptacle terminal is fused and fixed to the outside of the window structure.

Abstract: An apparatus comprises a laser emitter configured to transmit laser energy across an air gap to a separate device; a photodiode configured to detect laser energy received across the air gap from the separate device; and logic circuitry configured to initiate recurrent transmission of a laser pulse by the laser emitter; and end the recurrent transmission in response to detecting laser energy received by the photodiode from the separate device.

Abstract: A camera module which is particularly provided for vehicles. It includes a lens holder, a shaped part, and a sensor carrier. The lens holder is fastened on the sensor carrier via the shaped part with an adhesive).

Abstract: An optical receptacle, having an optical receptacle body and a support member. The optical receptacle body is in contact with the support member through a first contact surface, a second contact surface, and a third contact surface. The support member has a second fitting part fitting with a first fitting part disposed on the first contact surface of the optical receptacle body. The optical receptacle body is adhered to the support member by an adhesive disposed inside an adhesion recess on the support member and an adhesion through-hole in the optical receptacle body, with the optical receptacle body being set away from a virtual plane including an installation surface for the support member. The adhesion through-hole opens onto the third contact surface of the optical receptacle body and the surface of the optical receptacle body on the opposite side from the third contact surface.

Abstract: An optical receptacle is disclosed. The optical receptacle includes a ferrule that includes an inner hole extending in a first direction and a distal end face having an opening in the inner hole, an optical fiber disposed in the inner hole, the optical fiber having a first end exposed from the opening, a metal member that includes a first through hole extending in the first direction and holds the ferrule in the first through hole, a metal body that includes a second thorough hole extending in the first direction and holds the metal member in the second thorough hole, a low dielectric constant material formed inside the ferrule and outside the optical fiber. The low dielectric constant material has a dielectric constant lower than a dielectric constant of the ferrule.

Abstract: Aspects of the present disclosure relate to detecting an optical signal and/or optical power in a ferrule-less optical fiber. In certain embodiments, one or more optical detectors are incorporated into an adapter that is configured to interface with a connectorized or non-connectorized ferrule-less optical fiber. The optical detector detects the presence or absence, and/or the optical power level, of the optical signal being transmitted through ferrule-less optical fiber and produces an electrical output representative of the detected optical signal.

Abstract: An optical fiber connection system includes a first and a second optical fiber, each with end portions that are terminated by a first and a second fiber optic connector, respectively. A fiber optic adapter connects the first and the second fiber optic connectors. A fiber alignment apparatus includes V-blocks and gel blocks. Each of the fiber optic connectors includes a connector housing and a sheath. The end portions of the optical fibers are positioned beyond distal ends of the respective connector housings. The sheath is slidably connected to the connector housing and slides between an extended configuration and a retracted configuration. The sheath covers the end portion of the respective optical fiber when the sheath is at the extended configuration and exposes the end portion when at the retracted configuration. The end portions of the optical fibers are cleaned when slid between the V-blocks and the gel blocks.

Abstract: According to one implementation an assembly is provided that facilitates a coupling of one or more light diffusing optical fibers to one or more light emitting diodes. According to one implementation the assembly includes a light emitting diode positioned inside a cavity of a frame that is equipped with means to directly or indirectly electrically couple the anode and cathode of the light emitting diode to a printed circuit board. A proximal end portion of the light diffusing optical fiber is supported inside a through opening of a lid positioned over a front side of the frame. The light diffusing optical fiber includes a core that is surround by a cladding. According to some implementations the proximal end of the light diffusing optical fiber is butt-coupled to the light emitting diode with there being no gap between the proximal end of the fiber and the light emitting side of the light emitting diode.

Abstract: The disclosed embodiments provide an apparatus for connecting one or more optical fibers to an optoelectronic system. This apparatus includes a packaged optoelectronic module (POeM) comprising an optical connector, a silicon photonic (SiP) chip, an integrated circuit (IC) chip, at least one laser chip and a package substrate. The apparatus also includes an assembly adapter enclosing the POeM, wherein the assembly adapter includes a mechanical transfer (MT) ferrule cavity, which includes one or more coarse-alignment structures to guide an MT ferrule enclosing at least one optical fiber during assembly of the apparatus. The assembly adapter is comprised of a solder-reflow-compatible material to facilitate bonding the assembly adapter to a circuit board.

Abstract: There is provided a method, system and image capture device for determining a polarity of a multi-fiber cable link comprising a plurality of optical fiber links each connected between a first multi-fiber connector and a second multi-fiber connector, according to said polarity. Test light is injected into one or more of the optical fiber links via corresponding injection ports of the first multi-fiber connector, in accordance with a defined injection pattern; at least one polarity-testing image of the second multi-fiber connector is generated in which test light exiting at least one of the optical fiber links through one or more exit ports of the second multi-fiber connector is imaged as one or more spotlight spots in the polarity-testing image; and the polarity of the multi-fiber cable link is determined based on a pattern of said one or more spotlight spots in said polarity-testing image.

Abstract: An optical connector includes a first sub-assembly that is factory-installed to a first end of an optical fiber and a second sub-assembly that is field-installed to the first end of the optical fiber. The optical fiber and first sub-assembly can be routed through a structure (e.g., a building) prior to installation of the second sub-assembly. The second sub-assembly interlocks with the first sub-assembly to inhibit relative axial movement therebetween. Example first sub-assemblies include a ferrule, a hub, and a strain-relief sleeve that mount to an optical fiber. Example second sub-assemblies include a mounting block; and an outer connector housing forming a plug portion.

Abstract: An optical module includes a circuit board having, an electronic circuit formed therein and an optical circuit mounted thereon, and coupled to a first end of an inner optical fiber, a connector assembly to which a second end of the inner optical fiber is fixed, and a housing including a first housing including a slid surface on which a sliding surface included in the connector assembly slides so as to position the connector assembly, a second housing including an engaging protrusion engaged with the positioned connector assembly so as to fix the connector assembly, the second housing being bonded to the first housing and the housing being mounted with the circuit board.

Abstract: An example embodiment includes an optoelectronic module. The optoelectronic module may be configured to transmit out-of-band (OOB) data as an average optical power difference between optical signals. The optoelectronic module may include a first optical source, a second optical source, and an optical power control device. The first optical source may be configured to generate a first optical signal including first channel payload data on a first optical channel. The second optical source may be configured to generate a second optical signal including second channel payload data on a second optical channel. The optical power control device may be configured to vary average optical powers of one or more of the first optical signal and the second optical signal to create an average optical power difference between the first optical signal and the second optical signal that is representative of a logical bit of the OOB data.

Abstract: A connector assembly (1) comprises an outer housing (300); and a latch (330), which is carried by the outer housing (300), to allow a coupling of the connector assembly to a corresponding counter connector. Further, the outer housing (300) is configured to receive at least one of two different types of cables (100) through a first end and at least one of two different module mating interfaces (430, 432, 434) at a second end. In another embodiment the outer housing (300) is arranged movable on an inner housing (200), and the latch (330) is rotatably arranged on the outer housing (300).

Abstract: Methods and systems are provided for improving starting of an engine that has been stopped during humid ambient conditions. The methods and systems may reduce the possibility of starting an engine having liquid water in engine cylinders to improve engine starting. In one example, a laser is applied to a metal surface within the engine to vaporize water that may be in the engine due to condensation.

Abstract: The present disclosure discloses a plug protection cap that includes a main body, a connecting sleeve, and a traction stub. An accommodating cavity is disposed in the main body. An inlet is through the accommodating cavity that is disposed on an end face of one end of the main body. One end of the connecting sleeve detachably sheathes one end that is of the main body and that is away from the inlet, and the other end of the connecting sleeve is connected to one end of the traction stub in a rotatable manner. The present disclosure further discloses an optical fiber connector assembly, a fiber plug, and a network device.

Abstract: An expanded beam ferrule includes a first ferrule halve having reflective surfaces and a second ferrule halve, which together retain optical fibers. The reflective surfaces output light perpendicular to the mid-plane of the ferrule. A sleeve aligns the external surface of two similar ferrules, with the reflective surfaces of the respective ferrules facing each other. Output light from an optical fiber held in the first ferrule is bent and collimated by a reflective surface, transmitted to the facing reflective surface in a second ferrule aligned by the sleeve, which bends the light to input to the optical fiber held in the second ferrule. The ferrule components and/or sleeve are precision formed by high throughput metal stamping. The ferrule is incorporated in an optical fiber connector.

Abstract: Aspects and techniques of the present disclosure relate to a fiber optic connector including a connector body defining a central longitudinal axis that extends in a front-to-rear orientation. The connector body can include a front connector housing piece and a rear connector housing piece that may be aligned along the central longitudinal axis. A front end of the rear connector housing piece can be adapted to connect with a rear plug end of the front connector housing piece. The rear end of the rear connector housing piece can include a unitary fiber bend radius limiting structure. The unitary fiber bend radius limiting structure can be generally funnel-shaped. A ferrule assembly can be captured between the front and rear connector housing pieces with the rear connector housing piece functioning as a rear spring stop.

Abstract: A laser component includes a housing that includes a base section including a top side and an underside, wherein a plurality of electrical soldering contact pads are configured at the underside of the base section, the electrical soldering contact pads enabling surface mounting of the laser component, a plurality of electrical chip contact pads are configured at the top side of the base section and electrically conductively connect to the soldering contact pads, the housing includes a cavity adjoining the top side of the base section, and a laser chip is arranged in the cavity and electrically conductively connects to at least some of the chip contact pads.

Abstract: Examples of transceiver module assemblies may comprise a first transceiver module engaged with a first electrical device and including a first transceiver, a second transceiver module engaged with a second electrical device and including a second transceiver, and an electro-optical cable to connect the first transceiver module to the second transceiver module. The first transceiver module may receive an electrical signal and electrical power from the first electrical device, and the first transceiver may convert the electrical signal to an optical signal. The electro-optical cable may separately transmit the optical signal and the electrical power from the first transceiver module to the second transceiver module. The second transceiver may convert the optical signal back to the electrical signal and provide the converted electrical signal to the second electrical device.

Abstract: An optical connector according to the present disclosure is an optical connector for optically coupling a first optical transmission path and a second optical transmission path, including a first connector part disposed so as to cover at least a part of the first optical transmission path the first connector part including a first positioning portion for performing positioning with respect to the first optical transmission path a second positioning portion for performing positioning of the second optical transmission path held by the second connector part connected to the first connector part and a measurement auxiliary portion formed so as to correspond to the arrangement of the second positioning portion, wherein at least a part of the first positioning portion and at least a part of the measurement auxiliary portion are formed at positions that can be visually recognized simultaneously from the same direction.

Abstract: A light module for a motor vehicle comprising a heat sink comprising at least two mounting faces forming an angle (?) between them, at least two light guides, each comprising an input face and a branch, and, at least two light sources, each arranged at one of the input faces of the light guides which is associated with it, in which each input face is arranged facing one of the mounting faces of the heat sink and is adapted to couple the light rays emitted by the light source into the associated light guide.

Abstract: A mobile peripheral adapter has plural data and plural video ports disposed along a perimeter of a circular housing having first and second rotationally coupled portions. The video ports are coupled to a first video circuit board and the data ports are coupled to a second communications circuit board separate from the video circuit board. A USB cable includes video wirelines that couple to the video circuit board and other wirelines that couple to the communications circuit board, such as data, power and ground wirelines. A flexible cable interfaces control, power and ground between the video and communications circuit boards.

Abstract: An optoelectronic assembly for a printed circuit board (PCB) assembly is described herein. The optoelectronic assembly may include a component carrier for mounting an active component, and a connector assembly for achieving a coupling between the component carrier and PCB-side optical infrastructure on a printed circuit board (PCB). The connector assembly can include a plurality of optical fibers connected to the component carrier, a first optical connector connected to the optical fibers for coupling with the PCB-side optical infrastructure on the PCB, and a housing member for housing the optical fibers and the first optical connector.

Abstract: In an embodiment, an optoelectronic module includes a printed circuit board (PCB) and a lens block. The printed circuit board (PCB) includes at least one of an optical transmitting or receiving array. The lens block may be configured for directly coupling light between one of the optical transmitting or receiving array to optical fibers in an optical cable. A method may include directly coupling light between one of an optical transmitting or receiving array and a lens block, and further coupling the light through the lens block directly to an optical fiber of an optical cable externally coupled to the optoelectronic module.

Abstract: In an image transmission/reception system (1) including an active cable (10), an image transmission device (camera 30), and an image reception device (grabber 40), a transmission-side connector (11) of the active cable (10) includes a supplying section (111a) for supplying internal information indicative of an internal state of the transmission-side connector (11) to the image transmission device (30), and the image transmission device (30) includes a superimposing section (MUX 35) for superimposing the internal information on an image signal which is to be transmitted to the image reception device (40) via the active cable (10).

Abstract: An optical transceiver which is inserted and ejected with respect to a cage in a first direction is disclosed. The optical transceiver includes a slider having a slit including a slope in a second direction intersecting in the first direction, a housing supporting the slider to slide along the first direction, and a latch having a shaft sliding in the slit lining up in the first direction in response to a projection, the projection engaging the cage and standing out from a surface of the latch in the second direction. The housing has a pair of convexes contacted both surface in each other of area between the projection and the shaft of the latch, and the pair of convexes of the housing supports the latch to slide.

Abstract: A camera module is provided, including a frame, a holder, an image sensor, a plate, an electromagnetic driving assembly, and an elastic element. The frame connects the holder with the plate. The holder is configured to sustain an optical lens, and the image sensor is disposed on the plate. The elastic element connects the frame with the plate. The electromagnetic driving assembly is disposed on the frame and the plate, and is configured to drive the plate and the image sensor to move with respect to the frame and the holder.

Abstract: Embodiments of the present disclosure provide an optical assembly for high speed optical communications by combining a cover assembly including a lens and a cover post with a body assembly including a lens, reflection prism and body hole, which takes only a few passive optical alignments for providing aligned optical elements that have required multiple complex and sophisticated processes.

Abstract: A transmitter optical sub-assembly includes a body and a receptacle assembled to a front side of the body, the receptacle including a nose body, a split sleeve enclosed by the nose body, a first body disposed behind the split sleeve, and a fiber stub either glued or shrink fit or pressed fit on to the first body, a rear end of the split sleeve being slip fitted on to the fiber stub; wherein the nose body is made from deep drawing or cold forging process and is attached on to a front surface of the body.

Abstract: According to various embodiments, there is provided a sensor arrangement including a filter configured to provide an output signal having an output wavelength, the output wavelength having a dependence on a temperature of the filter; a temperature module configured to change the temperature of the filter; a controller circuit configured to control the temperature module for changing the temperature of the filter until the output wavelength increases with decreasing temperature; and a determination circuit configured to determine a dew point of an environment surrounding the sensor arrangement, based on a minimum value of the output wavelength and the dependence.