Abstract: A method and apparatus for providing a tracer function for networked cable systems used for data or power transmission. A self contained and self powered indicator circuit is described that enables tracing the location of both ends of a networked cable.

Abstract: A system includes an optical transceiver assembly, including a flip chip connection of a semiconductor die with a photonic transceiver that overhangs a substrate to which it is to be connected. The assembly further includes an alignment pin that is held to the semiconductor die at a micro-engineered structure in the semiconductor die. The alignment pin provides passive alignment of the photonic transceiver with an optical lens that interfaces the photonic transceiver to one or more optical channels.

Abstract: A transmission/reception optical module has an optical transmission subassembly 182, an optical reception subassembly 183, and a circuit board 1 wherein the circuit board 1 is formed into one member by a rigid/flexible substrate. Circuit board main bodies 2a, 2b, and an optical reception subassembly fixation region 4 are formed by rigid regions 5A, 5b, and 5P. An area provided between the circuit board main body 2a and the optical reception subassembly 4 is composed of a flexible region 6P. A part of the circuit board main body 2 is composed of a flexible region 6.

Abstract: There is described an optoelectronic device having a housing and a chip housed by the housing. At least a portion of the chip protrudes through an aperture in a wall of the housing. There is further provided an optoelectronic module comprising such an optoelectronic device and electronic control circuitry adapted to control the operation of the optoelectronic device.

Abstract: An assembly includes an optical device including an optical component and a plurality of supporting electrical components, a housing that is configured to house the optical component, a cap that is configured to substantially enclose the optical component in the housing, and a mounting member that is configured to removably electrically and mechanically connect the optical component to a printed board. In some examples, the housing does not house any electrical components of the optical device. The housing is physically separate from the mounting member and is configured to removably mechanically connect to the mounting member. The housing and mounting member define an electrically conductive pathway from the optical component to the printed board. When the cap is mechanically disconnected from the housing, the optical component may be exposed. The cap may also be configured to mechanically and optically connect an optical fiber assembly to the optical component.

Abstract: An optical fiber connector includes a connector hold, an optical fiber connector body, an elastic member, and a number of optical fibers. The connector hold defines a receiving recess and a position slot in communication with the receiving recess. The optical fiber connector body is engaged in the receiving recess of the connector hold. The optical fiber connector body includes a positioning post corresponding to and received in the position slot. The optical fibers pass through the connector hold and are attached to the optical fiber connector body. The connector hold includes a slide block received in the position slot, one end surface of the slide block contacts the elastic member, and the other end of the slide block is engaged with a distal end of the positioning post. The slide block is sized and shaped conforming to the position slot.

Abstract: A system for data communication connection in an architecture including an optical fiber communication line running from a communication service provider source to a proximity of at least one building, a fiber optic branch line extending from a point along the communication line generally towards the at least one building, and a receptacle, comprises a communication unit, a fiber optic cable coupled to the communication unit, and at least one connector adapted to couple the branch line to the fiber optic cable coupled to the communication unit. The connector may reside within the receptacle, and at least one of the communication unit, the cable, the branch line, the connector, and the receptacle may provide a visual indication that coupling of the branch line and the cable is effected.

Abstract: An optical transceiver includes a substrate, a plurality of laser components, a bracket and a plurality of lenses. The substrate defines a plurality of through holes, a plurality of receiving grooves and at least two fixing holes. The laser components are received in the plurality of receiving grooves and installed on the substrate. The bracket includes a top cover with an upper surface and one or more side walls. The one or more sidewalls include at least two positioning posts and one or more fixing surfaces. The positioning posts are engaged with the fixing holes to position the bracket to the substrate. The fixing surfaces are affixed on the substrate by an adhesive. The one or more sidewalls define one or more through channels extending from the one or more fixing surface to the upper surface. The lenses are installed on the bracket and correspond to the laser components.

Abstract: A combined optical and electrical interconnection module includes a flat cable comprising an optical transmission line and an electrical wire, and a printed circuit board including a light receiving module for receiving optical signals and/or a light sending module for sending optical signals and an optical waveguide for the optical signals to be transmitted therethrough or an optical block for bending the optical paths of the optical signals. The printed circuit board is electrically and optically connected to both ends or one end of the flat cable.

Abstract: A universal modular connector of the present invention mainly includes a base and a transforming module. The base has a first slot. A connecting socket is arranged in the base. The connecting socket has an opening and a plurality of conductive pins protruding out from the base. The transforming module has a circuit board, an optical component electrically connected to the circuit board, a signal transforming integrated circuit, and a plurality of conducting terminals. The transforming module is arranged in the first slot of the base. The conducting terminals are electrically connected to the conductive pins in the opening. The optical component receives an optical signal from an external wire, the signal transforming integrated circuit transforms the optical signal into a corresponding electronic signal, and then the electronic signal is transmitted to the conductive pins.

Abstract: On a mounting substrate 101, an LD element 102 and a wavelength converter element 103 are mounted as optical elements. An end of an optical fiber 105 is fixed, at a given length, in a fiber anchoring groove 301 of a sub-substrate 104. The sub-substrate 104 is mounted to the mounting substrate 101 with the surface supporting the optical fiber 105 opposing thereto, and the wavelength converter element 103 and the optical fiber 105 being coupled. By mounting of the sub-substrate 104 to the mounting substrate 101, the coupling position of the output end of the wavelength converter element 103 and the input end of the optical fiber 105 is provided an internal position that is a given distance from the end of mounting substrate 101.

Abstract: A universal modular connector includes a base and a transforming module. The base has a first opening thereon, and the base further has an optical component therein. The transforming module has a circuit board, a plurality of connection terminals, a first signal transforming integrated circuit (IC), and at least one fiber optic connector therein. The transforming module receives external electronic signal through the connection terminals, and transforms the received electronic signal into optical signal via the first signal transforming IC. The transforming module is connected with the base through the first opening, and the optical component of the base receives the transformed optical signal sent by the fiber optic connector of the transforming module. Therefore, the universal modular connector transmits the optical signal externally to an electronic device via the optical component.

Abstract: An optical connector mainly includes a base and a mount. The base has a first slot. The base has a receiving space for arranging the optical component. The mount has an adapting end inserted into the first slot. A connecting port is formed on the adapting end. The base is connected with an external wire through the connecting port. The adapting end has an opening corresponding to the position of a tunnel of the base. Thus, when the external wire is inserted into the connecting port, the optical component can receive an optical signal from the external wire through the tunnel of the base and the opening on the mount.

Abstract: In one example, a rotatable top shell is provided for an example optoelectronic device. The rotatable top shell includes a body defining a curved tongue on one end. The tongue is configured to rotate about a complimenting curved mating surface of a bottom shell of the optoelectronic device to allow the body to rotate between an open position and a closed position. The rotatable top shell further includes means for securing the rotatable top shell relative to the bottom shell. The means for securing the rotatable top shell may include one or more of: a plurality of nubs defined along at least one edge of the body, a hole defined in the body for receiving a retention pin of the bottom shell, two sides for being received within a main cavity of the bottom shell, or the like.

Abstract: Systems and methods for direct cooling of transceivers, including transceivers used in electrical and optical communications systems. An electrical system includes a transceiver module with a housing that contains a plurality of apertures to allow air flow into and out of the transceiver module. The transceiver includes an internal heat sink located within the housing of the transceiver module, where the internal heat sink is thermally coupled to at least one internal component of the transceiver module. The electrical system also includes a cage for receiving and electrically connecting to the transceiver module.

Abstract: A planar light circuit may be mounted in the housing a one-point mounting. The one-point mounting may reduce the tendency of thermal deformations in the housing to be transmitted to the planar light circuit.

Abstract: There are provided high power laser connectors and couplers and methods that are capable of providing high laser power without the need for active cooling to remote, harsh and difficult to access locations and under difficult and harsh conditions and to manage and mitigate the adverse effects of back reflections.

Abstract: A suspension board with circuit includes a metal supporting board; an insulating base layer formed on the metal supporting board; a conductive pattern formed on the insulating base layer; an insulating cover layer formed on the insulating base layer so as to cover the conductive pattern; and an optical waveguide. The optical waveguide is provided on the metal supporting board separately from the insulating base layer, the conductive pattern, and the insulating cover layer.

Abstract: An opto-electronic module connector system is mountable on a system substrate, such as a printed circuit board, in a variety of configurations or orientations and includes an electromagnetic interference (EMI)-shielding enclosure, a connector assembly, and a socket. The connector assembly includes a connector body, a connector printed circuit board, a substantially planar contact holder, electrical contact fingers mounted on the contact holder, and an opto-electronic module. When the EMI-shielding enclosure and socket are mounted on the system substrate, a user can readily insert the connector assembly into the EMI-shielding enclosure and plug it into the socket. A user can likewise readily remove the connector assembly from the EMI-shielding enclosure and socket for maintenance, cleaning, repair or other purposes.

Abstract: A fiber optic component includes a body having at least one receptacle configured to receive a fiber optic connector, a shutter base mounted to the body at a mounting location adjacent to the at least one receptacle, and a first shutter connected to the shutter base by a first hinge. The first shutter, first hinge and shutter base are unitarily formed, and the first shutter is shiftable from a first position biased against the body and covering the at least one receptacle to a second position biased to an angularly spaced position relative to the first position.

Abstract: The present invention provides a multi-channel transceiver module comprising a unitary housing having a first channel body and a second channel body. Each channel body includes a male plug end and a receptacle plug end. A bridge member is provided for joining the first and second bodies. The bridge members disposed at the receptacle end. A gap is provided between the plug ends of each channel body. The gap extends from each plug end to the bridge member to partially divide each channel so that each plug end is insertable within a separate receptacle cage.

Abstract: A telecommunications assembly includes a chassis and a plurality of fiber optic splitter modules mounted within the chassis. Each splitter module includes at least one fiber optic connector. Within an interior of the chassis are positioned at least one fiber optic adapter. Inserting the splitter module through a front opening of the chassis at a mounting location positions the connector of the splitter module for insertion into and mating with the adapter of the chassis. The adapters mounted within the interior of the chassis are integrally formed as part of a removable adapter assembly. A method of mounting a fiber optic splitter module within a telecommunications chassis is also disclosed.

Abstract: The invention relates to a hermetic feedthrough of an optical fiber into a package for an optical module, that includes a package ferrule hermetically attached to the package or integral therewith, a fiber ferrule hermetically sealed around the optical fiber, and a compression sleeve hermetically sealed around the package ferrule. The compression sleeve is hermetically sealed to the fiber ferrule or integral therewith, and wherein a coefficient of thermal expansion (CTE) of the compression sleeve is greater than a CTE of the package ferrule so that a joint between the compression sleeve and the package ferrule is under compressive stress.

Abstract: Fiber optic connectors and components for fiber optic connectors with improved side-loading performance are disclosed along with methods for making the same. The fiber optic connector includes a ferrule and a ferrule holder where the ferrule holder may be disposed within a housing. The ferrule holder has a forward portion with a spherical feature for cooperating with the housing, thereby allowing relative movement therebetween. Specifically, the spherical feature of the ferrule holder permits rotational translation of the ferrule holder in two degrees of freedom relative to the housing and inhibits the longitudinal translation of the ferrule holder in same two degrees of freedom relative to the housing, thereby providing improved side-loading performance.

Abstract: When a light guide of a sleeve is inserted into a through-hole, a positioning rib is mounted in the holding recess and the sleeve is positioned in the housing. When a transmitting optical module is mounted in a housing space, a positioning protrusion of the sleeve enters a positioning recess of the transmitting optical module and contacts a stepped surface of the transmitting optical module. Thus, the transmitting optical module and a transmitting sleeve are positioned so as to face each other with high precision, and thereby the light transmission efficiency can be increased.

Abstract: A semiconductor submodule includes a substrate (10) as a first substrate having at least one hole, and at least one optical semiconductor device (16) disposed such that light travels through the hole, a substrate (11) as a second substrate having a semiconductor device (26) for driving the optical semiconductor device (16) and amplifying signals and an electrical connector (28) for inputting and outputting electrical signals from and to the outside, and a flexible cable (12) electrically connecting an end of the substrate (10) and an end of the substrate (11) and allowing the first substrate to be folded opposite to the surface on which the optical semiconductor device is mounted.

Abstract: Radio frequency identification (RFID)-equipped communication components are disclosed. The communication components can include fiber optic components, such as fiber optic connectors and fiber optic adapters as examples. An RFID-equipped circuit is provided in the communication components to communicate information. In order that the electrical circuit be provided in the communication component without altering the communication component connection type, the circuit may be disposed in at least one recessed area of the communication component housing. In this manner, the communication component maintains its connection type such that it is compatible with a complementary communication component connection type for backwards compatibility while also being RFID-equipped.

Abstract: A USB connector is provided that has an OE module and high-speed electrical connections integrated therein. The OE module includes an optical module, at least one laser diode, at least one photodiode, an optical transceiver IC, and a PCB. The optical module, the laser diode, the photodiode, and the IC are mounted on a surface of the PCB. The OE module is secured within the USB connector. The PCB includes conductive traces and electrical contact pads. The conductive traces electrically connect the IC with the contact pads. The contact pads are electrically connected via through holes formed in the PCB to the high-speed electrical connections, which, in turn, are electrically connected to conductive traces of a motherboard or a computer.

Abstract: Printed circuit board (PCB) positioning spacers in an optoelectronic module. In one example embodiment, an optoelectronic module includes a housing comprising a top shell and a bottom shell, top and bottom printed circuit boards (PCBs) at least partially enclosed within the housing, and a spacer positioned between the first and second PCBs. The spacer includes top and bottom surfaces, a plurality of top posts extending from the top surface, and a bottom post extending from the bottom surface. The top posts extend through openings in the top PCB to contact one or more inside surfaces of the top shell. The bottom post extends through an opening in the bottom PCB to contact an inside surface of the bottom shell.

Abstract: A fiber optic cable assembly includes a fiber optic connector and a fiber optic cable having at least one strength element, the connector and cable held together by a crimp band. The crimp band may include at least one lateral aperture on at least one end for inspecting the disposition of the strength element prior to crimping to ensure a uniform distribution of the strength element.

Abstract: An apparatus for connecting user equipment to a broadband network includes a chassis having attachment points for connection to a supporting surface and a guide that permits entry of a communication cable. A cable termination unit may be mounted on the chassis such that a cable that is led through the guide can be connected and provided with a termination to which functional connections can be made. A cover may be mounted on the chassis in such a way as to be removable and reattachable to allow access to the chassis. The chassis may include mounting points for connecting at least one functional module to the communication cable and for allowing different communication functions to be provided to user equipment that is connected to the network via the apparatus.

Abstract: A coupling for the detachable connection of a fiber-optical light guide to a coupling counterpart including a coupling body that is connected to a fiber-optical light guide frame, including a gripping casing that circumferentially surrounds the coupling body at least in sections, and including at least one locking hook that is movably held in a radially resilient manner for the locking engagement behind at least one locking projection of the coupling counterpart, whereby the gripping casing is rotatably supported on the coupling body and the at least one locking hook can be lifted out of the locking engagement by a rotary movement of the gripping casing. A coupling device including a coupling and a coupling counterpart.

Abstract: A connector holder fixes an optical connector assembled at a leading end of an optical fiber to an optical module having a light input/output end so that the optical fiber and the light input/output end is optically connected. The connector holder is provided with a holding section for storing at least a part of the optical connector, and a cover section attached to the holding section to be freely opened and closed. The cover section is provided with a cover section main body, and a pressing section which presses the optical connector toward the optical module.

Abstract: An optical fiber connector includes a holder, a housing fixed on the holder, a clamping member for clamping an optical cable having an optical fiber, a protecting member positioned in the housing. The protecting member defines a bore for the optical fiber of the optical cable to moveably pass through. The optical fiber connector also includes a first elastic member, in which one end of the first elastic member resists the protecting member, and the other end of the first elastic member resists the clamping member, so as to extend the optical fiber out of the protecting member and the protecting member to partly protrude out of the housing.

Abstract: An inline optoelectronic converter configured to convert electrical signals to optical signals and to convert optical signals to electrical signals. The converter is external to the avionic computer and connected to the avionic computer at a location spaced apart from the avionic computer. The converter is configured to be integrated into an existing wiring bundle of the avionic computer. Also disclosed is a method of retrofitting an avionic computer by connecting an optoelectronic converter to the computer. The method comprises connecting the converter to an existing wiring bundle of the avionic computer at a location spaced apart from the avionic computer.

Abstract: For a less load to a shutter and secure motions of the shutter without damaging a ferrule, a rear stopper guide (22) and an intermediate spring guide (23) covering an upper side of a hold of an optical plug, and an outer cover (24) covering a front outer periphery of the hold are provided; the outer cover (24) is pushed by an optical connector adapter (Q) to move from a front end position of the hold to a rear end position, an inner side of the outer cover (24) is provided with a shutter (21) which can be swung from a lid close position to a lid open position, and the shutter (21) is automatically opened and closed by a shutter automatic opening and closing mechanism (S) in accordance with a rack and pinion system, working with rearward and forward movements of the outer cover (24).

Abstract: An optical transceiver has a projection covering member that can suppress EMI noise radiated from a pig-tail part. An elastic covering member covers a projection which includes an optical coupler of an optical sub assembly. The covering member is made of a conductive elastic material having a predetermined resistivity. At least a part of an outer circumference surface of the elastic covering member comes into intimate contact with an outer periphery of a conductive opening part of a case for the optical transceiver while an inner circumference surface of the elastic covering member comes into intimate contact with the projection.

Abstract: In a package (5) formed by a supporting portion (5a) for supporting a light emitting portion (7) or a light receiving portion (9) for emitting or receiving an optical signal, and a lid (5b) for covering the supporting portion (5a); the supporting portion (5a) or the lid (5b) includes a light guide mounting surface (22) for supporting at least one end including an incident/exit port of the optical signal in a film light guide (4) for optically coupling with the light emitting portion (7) or the light receiving portion (9) and transmitting the optical signal; and a length (D) in a Z-direction serving as a perpendicular direction with respect to the light guide mounting surface (22) from the light guide mounting surface (22) of the supporting portion (5a) or the lid (5b) to the lid (5b) or the supporting portion (5a) facing the light guide mounting surface (22) is longer than a length (d) in the Z-direction in a region of the film light guide (4) supported by the light guide mounting surface (22).

Abstract: An optical transceiver easily set within the cage of the host system. The optical transceiver of an embodiment provides a finger surrounding the housing of the optical transceiver. The finger has an rear edge, whose tip is bent downward so as to be received in the first groove of the housing, extending diagonally to the brim of the cage; and a reinforced portion with a U-shaped cross section tightly set within the second groove of the housing.

Abstract: An optical module is disclosed where an optical coupling efficiency between an optical device and an external fiber may be improved. The optical module includes an optical receptacle and a device unit assembled with the optical receptacle only via a stub as forming a gap to isolate these two components. The gap is filled with insulating resin or tightly covered by an insulating ring to reinforce the stub to be hard for an increased moment by the optical assemblies in the device unit.

Abstract: An optical device packaging structure, including a main body (B). One or more V-shaped grooves (B1) are formed in the main body (B), and an optical signal transmission hole system communicated with two side walls of the V-shaped groove (B1) is disposed in the main body (B). The optical signal transmission hole system includes an optical signal transmission hole perpendicular and/or parallel to the central line of the included angle of the V-shaped groove, and the included angle of the V-shaped groove is 90°±10°. An optical device module packaged by the optical device packaging structure is also provided.

Abstract: A plug connector (10) for mating with a receptacle connector (200) includes an insulative housing (1) having a base portion (11) and a tongue portion (12) extending forwardly beyond the base portion; a set of contacts (2) having contacting portions (211, 221) attached to the tongue portion for mating with the receptacle connector; and a metal shell (7) having a chamber (79) with the tongue portion extending therein, a plurality of openings (74) formed thereon for being locked in by a plurality of resilient fingers (2051) of the receptacle connector, and a set of embossments (76) located at front of the openings and protruding outwardly of the metal shell for interferentially engaging with the resilient fingers (2051).

Abstract: An optical transceiver module is provided with a delatch device that is configured for pushing and pulling an optical transceiver module into and out of a cage. The delatch device includes an elongated handle having at least one strength member integrally formed therein or secured thereto that provides the handle with a sufficient moment of inertia to prevent the handle from bending or buckling when a force is being applied to the elongated handle to push an optical transceiver module into a cage. The elongated handle allows a module to easily be inserted into a cage by a user without the user having to directly access the front face of the module.

Abstract: An AOC connector is provided that has a molded plastic leadframe that obviates the need to use an optical connector in the AOC and that is capable of operating over a wide temperature range and a large number of temperature cycles. The AOC connector includes a plastic optical port that is adapted to be connected via an optically-transparent adhesive material to an end of an optical fiber cable.

Abstract: A transceiver includes a lead-frame, a signal emitter, a signal receiver, and a coupling lens. The signal emitter and the signal receiver are attached on a same pad of the lead-frame. The coupling lens covers the signal emitter and the signal receiver. Since the positions of the signal emitter and the signal receiver are adjacent to each other, the coupling lens can be used to couple the signal emitter and the signal receiver for transmitting and receiving signals.

Abstract: An electro-optical module includes an optical lens block, a fiber connector, and a metal latch member adapted to hold the assembly of the optical lens block and the fiber connector together and on a printed circuit board. The latch member includes a metal sheet substantially covering the assembly, depending legs for snap-locking to the printed circuit board, springs at a rear end of the assembly and compress during insertion of the fiber connector, and latching arms with hooks for latching onto two opposite end portions of a front end of the assembly after the insertion and release of the springs.

Abstract: An optical connector 1 is for connecting a connection object 10 to an optical module 21. A slider 3 is slidably held by a housing 2 adapted for positioning the connection object and the optical module. The housing has a first positioning portion for receiving the connection object. The slider has a first pressing portion 3a for elastically pressing the connection object in a first direction toward the first positioning portion and a second pressing portion 3e that elastically acts in a second direction perpendicular to the first direction.

Abstract: An optical transceiver disclosed provides an OSA, a circuit board, a housing, a holder and a electrically conductive nonwoven material. The housing provides the first space that provides an optical receptacle and receives an external optical connector, and the second space within which the circuit board is installed. Two spaces are divided by a partition wall with a cut to pass the sleeve of the OSA. The nonwoven material, which is put between the partition wall and the holder, fills a gap formed between the sleeve and the cut.

Abstract: An optical module having a second connector unit mounted on the bottom of a first connector unit to reduce the size of the radiation member and the optical module. The optical module includes a first connector unit, a radiation member provided on a first side of the first connector unit to support the first connector unit and radiate heat, a second connector provided on the first connector unit to electrically connect the first connector unit to a PCB, and a fastening member provided on surfaces of the first and second connector units, which face each other, to fasten the first and second connectors to each other. The optical module is advantageous reduces the size of the radiation member and renders a more compact optical module.

Abstract: One embodiment includes communications module having a release slide and a boot. The release slide includes a main body, a plurality of arms, and a plurality of coupling structures. The arms extend from a first end of the main body. The coupling structures extend from a second end of the main body opposite the first end. The boot is disposed over the coupling structures of the release slide and defines a cavity configured to slidably receive a communications cable.