Abstract: An alignment apparatus according to one embodiment, includes: a first and a second stage; a first and a second detector; a first and a second moving mechanism; and a controller. The first and second stages are configured to respectively hold a first and a second semiconductor substrate on which a first and a second alignment mark are respectively disposed. The first and second moving mechanisms are configured to respectively move the first and second stages relatively to each other. The controller is configured to perform the following (a), (b). (a) The controller control the detectors and the moving mechanisms to cause the first detector to detect the second alignment mark and to cause the second detector to detect the first alignment mark. (b) The controller calculate a position deviation between the substrates in accordance with results of the detections.

Abstract: A laser cleaning system including a laser source, an energy-transferring optical fiber, a laser cleaning head, a coreless motor, a connection lens barrel, and a mirror.

Abstract: A light source package includes: a substrate; a first light source device disposed on the substrate, and configured to emit a light of a first wavelength; a second light source device disposed to be spaced apart from the first light source on the substrate, and configured to emit a light of a second wavelength, different from the first wavelength; and a light transmissive structure disposed above first and second light source devices, and including at least one first lens configured to increase a beam angle of the light of the first wavelength and at least one second lens configured to reduce a beam angle of the light of the second wavelength.

Abstract: An optical fiber adapter structure, comprises a metal flange, a tubular housing, an insulating ring, an optical fiber stub, and a shielding annulus. The optical fiber stub is embedded into the metal flange; the shielding annulus is fixed at a bottom of the metal flange by means of a conductive adhesive; the shielding annulus covers an end of the optical fiber stub and is provided with a reserved hole only for laser signals to pass through; the tubular housing is sleeved to the bottom of the metal flange; and the tubular housing is insulated from the metal flange by means of the insulating ring. The conductive adhesive adheres the shielding annulus made of conductive material to a tail end of the metal flange and maintains complete electrical contact therebetween, such that the electromagnetic wave radiation between the interior of optical device and the exterior of metal flange is reduced.

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: A memory system of embodiments includes a container, a first circuit board, a second circuit board, and an optical cable. The container has a hole connecting inside and outside the container. The first circuit board is disposed outside the container and has a first circuit to convert a first electric signal to an optical signal. The second circuit board is disposed inside the container and has a memory device, and a second circuit to convert the optical signal into a second electric signal and storing the second electric signal in the memory device. The optical cable transmits the optical signal from the first circuit board through the hole to the second circuit board.

Abstract: [Object] To provide an optical coupling device that efficiently receives an optical signal from an optical fiber and has improved communication quality, and an optical communication system using the same. [Solving Means] An optical coupling device according to the present technology includes a light receiving and emitting device and an optical device. The light receiving and emitting device includes a light emitter that emits outgoing light, and a light receiver that receives incident light from outside. The light receiver has a light passing part through which the outgoing light passes. The light passing part is arranged on an optical axis of the incident light. The optical device causes incident light around the optical axis of the incident light to be refracted so as to be apart from the optical axis and to enter the light receiver.

Abstract: Provided is an optical connector used for connecting an optical waveguide substrate and an optical-fiber connector member, where the optical connector comprises a plurality of positioning structures, each having a cylindrical hole for inserting another end of a pin which has an end inserted into the connector member, and a groove formed on a second surface perpendicular to a first surface on which an open end of the hole is located, and where the groove and the hole are continuous, the groove has an arc-shaped cross section, and a center of a circle formed by a cross section of the hole and a center of an arc formed by the cross section of the groove are identical, and when the optical connector is coupled to the optical waveguide substrate that comprises a plurality of protrusions having a rectangular cross section, in each of the plurality of positioning structures, at least two corners of a corresponding protrusion among the plurality of protrusions are supported by an inner wall of the groove.

Abstract: Provided is a laser reflow apparatus for reflowing electronic components on a substrate disposed on a stage, the apparatus including: a laser emission unit comprised of a plurality of laser modules for emitting a laser beam having a flat top output profile in at least one section of the substrate on which the electronic components are disposed; a camera unit comprising at least one camera module for capturing a reflowing process of the electronic components performed by the laser beam; and a laser output control unit configured to generate a control signal for independently controlling the respective laser modules of the laser emission unit based on a signal output from the camera unit and apply the control signal to the laser emission unit.

Abstract: A transmitter optical sub-assembly, includes a prism body, a first lens, and a plug-in. The prism body includes a light inlet end and a light outlet end, the first lens is disposed between the light outlet end and the plug-in, and the plug-in includes a contact end. The contact end is located on a surface that is of the plug-in and that is away from the first lens, a center of the contact end is located on a focus on an optical path of the first lens, and the contact end is arc-shaped for a purpose of a gapless interconnection with an optical fiber, to reduce end face reflection of the contact end. An optical transceiver assembly includes the transmitter optical sub-assembly, and has comparatively small reflection and a comparatively small return loss of an optical fiber end face.

Abstract: An optoelectronic module. In some embodiments, the optoelectronic module includes: a substrate; a digital integrated circuit, on an upper surface of the substrate; and a frame, secured in a pocket of the substrate. The pocket is in a lower surface of the substrate, and the substrate includes an insulating layer, and a plurality of conductive traces.

Abstract: A three-dimensional (3D) sensing apparatus together with a projector subassembly is provided. The 3D sensing apparatus includes two cameras, which may be configured to capture ultraviolet and/or near-infrared light. The 3D sensing apparatus may also contain an optical filter and one or more computing processors that signal a simultaneous capture using the two cameras and processing the captured images into depth. The projector subassembly of the 3D sensing apparatus includes a laser diode, one or optical elements, and a photodiode that are useable to enable 3D capture.

Abstract: A power and optical fiber interface system includes a housing having an interior. A cable inlet is configured to receive a hybrid cable having an electrical conductor and an optical fiber. An insulation displacement connector (IDC) is situated in the interior of the housing configured to electrically terminate the conductor, and a cable outlet is configured to receive an output cable that is connectable to the IDC and configured to output signals received via the optical fiber.

Abstract: Disclosed is a semiconductor radiation detector assembly including a detector chip having a front side for receiving radiation and a back side; and a flexible substrate including a center portion having its front side attached to the back side of the detector chip and a plurality of strips extending from the center portion and bent to protrude away from the detector chip, wherein the flexible substrate includes a plurality of conductive tracks that extend on a surface of the strips from the center portion towards lateral ends of the strips for electrical coupling and mechanical attachment to one of a plurality of contact pins, and wherein the detector chip is electrically coupled to at least one of the conductive tracks.

Abstract: An optical fiber connector module for coupling to a ferrule terminated to at least one fiber in a ribbon cable is provided. The optical fiber connector module may include a first connector body member for coupling to the ferrule, the first connector body member including at least one alignment component coupling section, at least one biasing component coupling section, and a first through-channel for the ribbon cable. The optical fiber connector module may include a second connector body member coupled to the first connector body member, the second connector body member including at least one biasing component coupling section, a second through-channel for the ribbon cable, and an open side spanning the length of the second connector body member providing access to the second through-channel for the ribbon cable.

Abstract: Disclosed is an outdoor optical fiber connection assembly, including an SC optical fiber connector, an LC optical fiber connector, and an optical fiber adapter for communicatively connecting the SC optical fiber connector with the LC optical fiber connector. In the connection assembly of the disclosure, the optical fiber connector and the optical fiber adapter are respectively provided with an elastic member, so that they are tightened under a pre-tightening force after connected. Furthermore, by arranging multiple sealing structures at connection positions of the connection assembly, the sealing performance of the connecting components is enhanced. By improving the internal structure of the optical fiber connector, the stop ring cannot rotate after being assembled, which has a good circumferential positioning effect, can prevent internal core wires from twisting, has a high quality in optical fiber docking, is not prone to displace the optical fibers after docking, and is high in reliability.

Abstract: A universal sub slot module is configured to be inserted in a slot in a hardware module that is configured to be inserted in one of a chassis and rack mounted unit. The universal sub slot module includes a printed circuit board; an optics component on the printed circuit board; a data plane and a control plane on the printed circuit board and communicatively coupled to the optics components; and connectors on the printed circuit board and communicatively coupled to the data plane and the control plane, wherein the connectors are configured to connect to corresponding connectors in the one or more hardware modules.

Abstract: An optoelectronic module may include a housing enclosing at least one optical transmitter or receiver, and a slider configured to move with respect to the housing. The slider may include at least one protrusion configured to engage with a cage sized and shaped to receive the housing, and a retainer configured to engage both the slider and the housing to retain the slider with respect to the housing. The retainer may include a first protrusion sized and shaped to be positioned in a slot defined by the housing, and a second protrusion sized and shaped to abut the slider.

Abstract: An optoelectronic module may include a housing enclosing at least one optical transmitter or receiver, a slider configured to move with respect to the housing, and a retainer configured to engage both the slider and the housing to retain the slider with respect to the housing. The slider may include a resilient tab and at least one protrusion configured to engage a cage sized and shaped to receive the housing. The retainer may include a first end portion configured to abut the resilient tab of the slider.

Abstract: Provided is an optical module comprising a substrate, a holder, and a spacer. An optical waveguide is formed in/on the substrate and end parts thereof are protruding from one surface of the substrate. The holder holds an optical fiber and exposes one end part of the optical fiber in such a manner that the one end part of the optical fiber can be optically connected to the end parts of the optical waveguide at a side of one surface of the holder. The spacer is held the one surface of the substrate and the one surface of the holder.

Abstract: The present invention provides an optical signal transmission device, including a lens base, a cover plate, an optical fiber plug and a printed circuit board (PCB), wherein an insert block is formed at a front end of the optical fiber plug, and a plurality of optical fibers penetrate the optical fiber plug; a socket is provided at a rear end of the lens base, the insert block is inserted into the socket and the two closely cooperate with each other; a recess is provided in the top of the lens base, and a reflective bevel is formed on the inner wall of the recess; and the cover plate is stacked on the top of the lens base, downwardly-extending fastening plates are respectively formed at peripheral edges of the cover plate.

Abstract: A laser alignment system is used to align an output fiber with a fiber laser, for example, when coupling a feeding fiber to a process fiber using a beam coupler or switch. The alignment system includes a laser alignment apparatus that is coupled at a first end to the output fiber and at a second end to a beam dump/power meter. The alignment apparatus defines a light passage and a light capture chamber along the light passage. When light is not aligned into the core of the output fiber, at least a portion of the light passing out of the output fiber will be captured by the light capture chamber and detected by a photodetector in optical communication with the light capture chamber. By monitoring the readings of the photodetector, the output fiber may be properly aligned with the laser light from the fiber laser.

Abstract: The disclosure provides a socket connector including a housing, a circuit board, an electronic device, a contact element, and a switch component. The housing has an insertion hole configured for an insertion of a plug connector. The circuit board is fixed in the insertion hole. The electronic component is disposed in the insertion hole. The contact element is located in the insertion hole. The contact element has a fixed end and a movable end, the fixed end is electrically connected to the circuit board, and the movable end is movable with respect to the circuit board. The switch component is movably located in the insertion hole and is in contact with the contact element. The switch component is configured to be movable by the plug connector so as to force the movable end of the contact element to electrically connect to or disconnect from the electronic component.

Abstract: An assembly system for assembling an optical die to an optical substrate includes test equipment configured to test optical couplers formed between the optical die and the optical substrate. The assembly system is configured to adjust an alignment of the optical die relative to the optical substrate until the optical couplers meet a performance metric. After the performance metric is met the optical die is permanently attached to the optical substrate.

Abstract: An optical ferrule includes a substrate formed of a diced wafer and a molded structure formed on the substrate. The molded structure may be formed of a curable material. The molded structure may include a plurality of grooves for positioning a plurality of optical fibers therealong, respectively, a plurality of reflective surfaces formed to reflect optical signals from ends of the plurality of optical fibers, respectively, or reflect incident optical signals towards the ends of the plurality of optical fibers, respectively, and an alignment structure disposed to be aligned to a corresponding alignment structure of a socket to which the optical ferrule is coupled.

Abstract: Provided is a package for an optical device and an optical device module that can reduce or prevent damage occurrence in an optical fiber optically coupled to an optical device while ensuring a good airtightness. A package for an optical device includes a package main unit that accommodates an optical device; a pipe portion that is provided in the package main unit and through which an optical fiber optically coupled to the optical device is inserted; and a fixing portion that is provided in the package main unit and to which one end of the optical fiber is fixed, and the pipe portion includes a first pipe section having a base end fixed to the package main unit and a second pipe section joined to a tip of the first pipe section, having a higher thermal expansion coefficient than the first pipe section, to be sealed by a sealing material.

Abstract: A test device for a TO-CAN laser includes a test socket, a coaxial waveguide substrate, and a test printed circuit board (PCB). The test socket comprises a coaxial waveguide tube accommodating a signal output pin of the TO-CAN laser and an electric-conducting slot accommodating a signal input pin of the TO-CAN laser. The coaxial waveguide substrate is respectively connected with a coaxial waveguide pin of the test PCB and the coaxial waveguide tube of the test socket. An electric-conducting slot pin of the test socket is connected with corresponding control pins of the test PCB.

Abstract: A line replacement unit includes a terminal controller, and a plastic optical fiber serial interface module (POFSIM) coupled between the terminal controller and the data bus. The POFSIM is configured to transmit digital optical signals to the data bus based on electrical signals received from the terminal controller, and transmit electrical signals to the terminal controller based on digital optical signals received from the data bus.

Abstract: A method for providing a vertical optical via for a semiconductor substrate is described. The semiconductor substrate has a front surface and a back side. A hard mask having an aperture therein is formed on the front surface. Part of the semiconductor substrate exposed by the aperture is removed to form a via hole. The via hole has a width not exceeding one hundred micrometers and a bottom. Cladding layer(s) and core layer(s) are provided in the via hole. The core layer(s) have at least a second index of refraction greater than that of the core layer(s). A portion of the semiconductor substrate including the back side is removed to expose a bottom portion of the core layer(s) and a bottom surface of the semiconductor substrate. The vertical optical via includes the cladding and core layers. The vertical optical via extends from the front surface to the bottom surface.

Abstract: It is desirable to provide a technology capable of improving reliability in light transmission and convenience at the time of connecting a transmission device to a cable with a simple circuit configuration. A transmitting device is provided which includes a connector receptacle unit connected to an optical-electrical composite cable, in which the connector receptacle unit includes a first electrode group, a second electrode group provided at a position rotated from the first electrode group by 180 degrees about a center of a main body of the connector receptacle unit as a reference, a first connection unit group for transmitting optical signals, and a second connection unit group for transmitting optical signals provided at a position rotated from the first connection unit group for transmitting optical signals by 180 degrees about the center of the main body of the connector receptacle unit as a reference.

Abstract: An optical module structure includes a substrate, an optical chip and an electrical chip that are fixedly coupled to the substrate. The optical module structure further includes an optical coupling structure fixedly coupled to the optical chip. A side of the optical chip that faces the substrate has a first reference plane, and at least one first alignment mark is provided on the first reference plane. The optical coupling structure has a second reference plane, and at least one second alignment mark is provided on the second reference plane. The first reference plane is aligned with the second reference plane, and the first alignment mark is aligned with the second alignment mark.

Abstract: There is provided an optical waveguide laminate in which an organic base material layer comprised of an insulation layer and a coverlay is laminated to one surface of an optical waveguide and in which a portion of the organic base material layer is lacking so that the optical waveguide is uncovered. Inequalities P?70% and P?Q?25% are satisfied where P is the laser light transmittance in at least a portion of the optical waveguide, the laser light having a predetermined wavelength range, and Q is the laser light transmittance of at least a portion of the organic base material layer. In this optical waveguide laminate, the organic base material layer laminated to the optical waveguide is elaborately removed without being impaired or thermally damaged by laser machining.

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 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 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 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: 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: 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: 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 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 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 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.