Abstract: Disclosed is a connecting harness that connects M first devices (where M is an integer equal to or greater than 1) and N second devices (where N is an integer equal to or greater than 2) using connecting cords each including at least one of an optical fiber cord and a metal cord. The connecting harness includes a connecting cord group including the M×N connecting cords, in which first connectors capable of being connected to the first devices are provided at one end of each of the connecting cords and second connectors capable of being connected to the second devices are provided at the other end of each of the connecting cords; a first bundling member bundling the connecting cords of the connecting cord group beside the first device in a predetermined number; and a second bundling member bundling the connecting cords of the connecting cord group beside the second device in a predetermined number.

Abstract: An optical connector holding two or more LC-type optical ferrules is provided. The optical connector includes an outer body, an inner front body accommodating the two or more LC-type optical ferrules, ferrule springs for urging the optical ferrules towards a mating receptacle, and a back body for supporting the ferrule springs. The outer body and the inner front body are configured such that four LC-type optical ferrules are accommodated in a small form-factor pluggable (SFP) transceiver footprint or eight LC-type optical ferrules are accommodated in a quad small form-factor pluggable (QSFP) transceiver footprint. A mating receptacle (transceiver or adapter) includes internal alignment slots configured to accept a corresponding alignment key on connector outer housing to ensure alignment and orientation for maximum signal transfer between opposing ferrule end faces.

Abstract: A duplex fiber optic adapter, comprising a housing having an integrated polarity reversal portion and a receiving portion is provided. The integrated polarity reversal portion comprises a first fiber optic connector assembly, including a first optic fiber assembly having a first coupling ferrule, a first connecting ferrule, and a first optic fiber therebetween, and a second fiber optic connector assembly, including a second optic fiber assembly having a second coupling ferrule, a second connecting ferrule, and a second optic fiber therebetween. The receiving portion comprises first and second ports, configured to receive a pair of ferrules of a fiber optic connector and through opposing ends, the first port is configured to receive the second connecting ferrule and the second port is configured to receive the first connecting ferrule. Following engagement, polarity reversal optical connection is established between the fiber optic connector and a mating fiber optic connector via the adapter.

Abstract: A temperature controlled multi-channel transmitter optical subassembly (TOSA), consistent with embodiments described herein, may be used in a multi-channel optical transceiver. The temperature controlled multi-channel TOSA generally includes an array of lasers to emit a plurality of different channel wavelengths. The lasers may be thermally tuned to the channel wavelengths by establishing a global temperature for the array of lasers such that the amount of heat communicated to each laser is substantially the same. The global temperature may be established, at least in part, by monitoring the shortest channel wavelength and/or a temperature of the lasers. The temperature of the lasers may then get increased via a shared heating device in thermal communication with the lasers until the shortest monitored wavelength substantially reaches the nominal shortest wavelength or the measured temperature substantially equals the global temperature.

Abstract: An optical connector device includes a first optical connector that has a first housing that holds a ferrule; and a second optical connector that has a second housing that houses an FOT and a light guide member. The second housing includes a ferrule insertion portion. The ferrule insertion portion has a ferrule insertion hole into which the ferrule can be inserted. An inner peripheral surface of the ferrule insertion hole has a ferrule fixing structure that fixes the ferrule inside the ferrule insertion hole to suppress play of the ferrule inside the ferrule insertion hole.

Abstract: An optical connector holding two or more LC-type optical ferrules is provided. The optical connector includes an outer housing, ferrules, a cable boot and one or more polarity keys. The keys are configured to change connector polarity from a first to a second polarity. A corresponding adapter with one or more slots within an adapter wall on opposing sides sized and shaped to accept a single or dual keyed polarity changeable connector.

Abstract: An optical connector (100) includes a housing (112) configured to contain one or more optical ferrules (121) disposed within the housing and accessible through an opening at a mating end of the housing. A cover (130) is disposed at the mating end, the cover configured to be rotated about a pivoting axis between a closed position an open position. An actuator (135, 136) is configured to cause the cover to rotate about the pivoting axis from the closed position to the open position.

Abstract: An optical connector device includes: a first optical connector that has a first housing; and a second optical connector that has a second housing that has formed therein a fitting space into which the first housing can be fitted. Fitting regulation convex portions are provided to an upper inner wall surface and a lower inner wall surface of the fitting space. Fitting regulation concave portions are provided in an upper surface and a lower surface of the first housing. First fitting regulation portions are formed at distal end of the fitting regulation convex portions. Fitting sliding surfaces are formed at the fitting regulation concave portions.

Abstract: A duplex fiber optic adapter, comprising a pair of fiber optic connector assemblies, a housing and a pair of ports positioned within the housing is provided. The housing has a pair of opening structures on one end, configured for fixed attachment of the pair of fiber optic connector assemblies, and a pair of polarity reversal connector openings on an opposing end, configured to receive a pair of ferrules of a fiber optic connector. When a fiber optic connector is inserted into the adapter and the adapter is coupled to a mating fiber optic connector, the pair of ferrules is engaged in the pair of ports of the housing and coupling ferrules of each pair of fiber optic connector assemblies is engaged in a pair of ports of the mating fiber optic connector, establishing a polarity reversal connection between the fiber optic connector and mating fiber optic connector via the adapter.

Abstract: A mode coupling connector system that includes a first and second fiber connector each coupled to a coupler housing. The first and second fiber connectors are positioned in first and second receiving cavities of the coupler housing, respectively. The first and second fiber connector each have a ferrule with a fiber receiving hole extending from an outer end to an inner end of the ferrule. The fiber receiving hole of the first and second fiber connector are in axial alignment. The mode coupling connector system further includes a mode coupling plate having a phase mask array of a plurality of phase masks. The mode coupling plate is positioned in a plate receiving hole of the coupler housing between the first and second receiving cavity and at least two phase masks of the phase mask array are circumscribed by the fiber receiving hole of both the first and second fiber connector.

Abstract: A fiber access terminal including a first assembly and a second assembly. The first assembly includes a first box body and an optical fiber adapter. The second assembly includes a second box body, an optical splitter, an optical fiber connector, and a plurality of optical fiber adapters. The optical fiber adapter of the first assembly is disposed outside the first box body. The optical splitter is disposed inside the second box body, and the optical fiber connector and the plurality of optical fiber adapters of the second assembly are disposed outside the second box body. A first end of the optical fiber connector is detachably connected to the optical fiber adapter of the first assembly, a second end of the optical fiber connector is connected to an input port of the optical splitter, and each output port is connected to one optical fiber adapter of the second assembly.

Abstract: The multichannel fiber optic connector, adapter, and contact retention method is disclosed. The connector includes a load carousel which enables handling, locating, retention, and, where needed, spring-loading of the plurality of single-fiber fiber optic ferrules supported within the connector, and the connector itself provides for independent axial and radial alignment of the fiber optic contacts. The adapter includes a plurality of optical alignment sleeves, and mating interfaces for two different connector types on differing sides of the adapter, wherein the fiber count of one connector type is an integral multiple of the fiber count of the other connector type, and wherein the contact pattern of the first connector type is repeated the same integral number of times within the contact pattern of the second connector type.

Abstract: A fiber optic connector having a push/pull tab wherein the push/pull tab travel is limited by an internal stop to release a connector from a receptacle, and the push/pull tab is releasably secured from connector. The push/pull tab has a plural of securing protrusions that secure the tab to the connector housing.

Abstract: A fiber optic connector having a push/pull tab wherein the push/pull tab travel is limited by an internal stop to release a connector from a receptacle, and the push/pull tab is releasably secured from connector. The push/pull tab has a plural of securing protrusions that secure the tab to the connector housing.

Abstract: A plug module is provided that includes a first mating end and a second mating end. The first mating end is configured to mate with a predefined port, such as a QSFP port. The second mating end can support two or more micro receptacles that allow the plug module to provide an octopus-like cable assembly without requiring the predetermination of a particular length of cable.

Abstract: An electronic module (EM) carrier includes a sliding bracket coupled to the EM carrier and a handle coupled to the sliding bracket. The handle and sliding bracket are configured to engage with a stationary chassis to hold the EM carrier at a first position in a bay of the stationary chassis when the handle is open. The sliding bracket is further configured to translate the EM carrier to a second position in the stationary chassis when the handle is moved from an open position towards a closed position. In the second position, an EM carrier connector of the EM carrier is engaged with a sled connector of a sled and, in the first position, the EM carrier connector is disengaged from the sled connector.

Abstract: An outer housing on a fiber optic connector allows for easier grasping to insert and remove a fiber optic connector, and in particular, in high density applications. The outer housing extends beyond a rear end of an inner housing. The outer housing also includes a way for a technician to see if the fiber optic connectors are installed correctly from a variety of positions relative to the installation.

Abstract: An extendable cable distribution device in accordance with an embodiment of the present disclosure can include a main block for receiving the end portion of a composite cable supplied from the outside, and providing the passage through which the received composite cable is distributed; at least one sub-block located to be detachable at one side of the main block, and for guiding the distribution direction of a part of the composite cable distributed while passing through the main block; and a connector located on the outer circumferential surface of the at least one sub-block, and electrically connected with at least part of the distributed cable. According to an embodiment of the present disclosure, it is possible to provide the cable distribution device capable of distributing the supplied composite cable and rotating the distributed cable depending upon the direction extended to the outside.

Abstract: The present invention discloses an optical fiber connector, comprising: a housing, a ferrule installed within said housing; an end sleeve, connecting to the rear end of said housing; and an optical cable clamp, installed by insertion within said end sleeve, being provided for the purpose of clamping an optical cable. Said optical cable is secured within said optical cable clamp, and after said optical cable clamp is inserted and secured within said end sleeve, the optical fiber of said optical cable is inserted within said housing and butt-joined with the embedded optical fiber within said ferrule. As a result of this, before the butt-joined optical fibers are locked in, the optical cable has already been secured within the optical cable clamp and fixed to the connector housing. Therefore, the butt-joined optical fibers cannot be separated due to the effects of unexpected pulling force, thus ensuring the optical fiber of the optical cable reliably abuts the embedded optical fiber.

Abstract: A sealing enclosure is configured to connect to a mating enclosure. The sealing enclosure loosely receives a connector within a connector volume so that the connector, which may be of a standard type used in electronic or optic data transmission, may be displaced within a plug face at the forward end of the connector volume. The connector may compensate variations in the position of a mating connector with respect to the mating enclosure. The sealing enclosure allows to seal off the connector volume and engage the sealing enclosure with a mating enclosure in a single motion. This is affected by having a cable seal interposed between an inner body and an outer body. If the outer body is moved forward to engage the mating connector, the cable seal is squeezed between the cable and the inner body sealing off the connector volume at the rearward end of the inner body.

Abstract: An optical module may include an optical subassembly having a receptacle. The receptacle may have a first diameter. The optical module may include a housing having a circular opening for receiving the receptacle. The circular opening may have a second diameter. The first diameter and the second diameter may be sized to reduce electromagnetic interference at a cut-off frequency from the optical module. The cut-off frequency may be defined by a data rate of at least one component of the optical module.

Abstract: An optical fiber connector includes a main unit and a housing unit. The main unit includes a boot and a connector module that has a rear part connected to a front end of the boot, and a front coupling end distal from the boot. The housing unit includes a sliding sleeve sleeved slidably around the connector module, and a light blocking member pivotally connected to the sliding sleeve. The sliding sleeve is operable between a light blocking position, where the light blocking member blocks light from the front coupling end, and a fiber coupling position, where the light blocking member rotates relative to the sliding sleeve and allows the front coupling end to be exposed from the sliding sleeve.

Abstract: Fiber optic connectors and connectorized fiber optic cables include connector housings having locking portions defined on the connector housing that allow the connector housing to be selectively coupled to a corresponding push-button securing member of a multiport assembly. Methods for selectively connecting a fiber optic connector to, and disconnecting the fiber optic connector from the multiport assemblies allow for connector housings to be forcibly and nondestructively removed from the multiport assembly.

Abstract: Fiber optic connectors and connectorized fiber optic cables include connector housings having locking portions defined on the connector housing that allow the connector housing to be selectively coupled to a corresponding push-button securing member of a multiport assembly. Methods for selectively connecting a fiber optic connector to, and disconnecting the fiber optic connector from the multiport assemblies allow for connector housings to be forcibly and nondestructively removed from the multiport assembly.

Abstract: An optical fiber connector includes a body member, a positioning member, a plastic portion, and an optical fiber assembly. The body member includes a first positioning hole and a concave portion. The positioning member includes a first spacing board and at least one positioning sheet. The first spacing board is provided with a second positioning hole and a protrusion. The second positioning hole corresponds to the first positioning hole, and the protrusion corresponds to the concave portion. The at least one positioning sheet is provided with a third positioning hole corresponding to the second positioning hole. The plastic portion is formed at the third positioning hole. The optical fiber assembly includes a bare fiber and a protective layer, such that the bare fiber passes through the third positioning hole, and is enveloped by the protective layer however with at least an end of the bare fiber uncovered.

Abstract: The invention relates to the field of optical communication network modules, and provides a 4-channel CWDM QSFP optical module, comprising a QSFP base and four optical transmitting sub-devices. The four optical transmitting sub-devices are mounted on the base in parallel, and there is a gap between each of the optical transmitting sub-devices and the base. The QSFP optical module further includes CWDM optical components for multiplexing 4-channel optical signals emitted by the four optical transmitting sub-devices. The CWDM optical components comprise a single fiber pigtail for transmitting the multiplexed optical signal, the single fiber pigtail being at least partially located in the gap. The 4-channel CWDM QSFP optical module of the invention connects the four optical transmitting sub-devices with the CWDM optical components by a reasonable method of optical fiber winding, thereby solves the problem that it is difficult to achieve single-mode fiber coupling of four LDs in a small space.

Abstract: A fiber optic cassette including a body defining a front and an opposite rear and an enclosed interior. A cable entry location is defined in the body for a cable to enter the interior of the cassette. The cable which enters at the cable entry location is attached to the cassette body and the fibers are extended into the cassette body and form terminations at connectors. The connectors are connected to adapters located at the front of the cassette. A front side of the adapters defines termination locations for cables to be connected to the fibers connected at the rear of the adapters. A cable including a jacket, a strength member, and fibers enters the cassette. The strength member is crimped to a crimp tube and is mounted to the cassette body, allowing the fibers to extend past the crimp tube into the interior of the cassette body. A strain relief boot is provided at the cable entry location.

Abstract: An optical cable subassembly includes one or more optical waveguides, at least light coupling unit comprising a first attachment area permanently attached to the optical waveguides, and at least one cable retainer comprising a second attachment area permanently attached to the optical waveguides and adapted to be installed in a housing. A length of the optical waveguides between the first attachment area and the second attachment area allows a bend in the optical waveguides that provides a predetermined mating spring force at a predetermined angle of the light coupling unit when installed in the housing.

Abstract: A fiber optic connector is disclosed that includes a plug body having a plug end and a connector core that mounts within the plug body. The connector core includes a ferrule subassembly including a ferrule, a ferrule hub that attaches to the ferrule, a spring holder and a connector spring. The ferrule sub-assembly is assembled with the connector spring pre-compressed to an initial compressed state prior to mounting the connector core within the connector body. The plug body and the core are configured such that the connector spring is moved from the initial compressed state to a final compressed state when the connector core is loaded in the plug body. In certain examples, tuning features can be integrated into the connector core.

Abstract: A system for connecting a fiber optic connector to a fiber optic adapter includes various alternative improvements, including improvements to the shutter, the alignment device, and the adapter in general.

Abstract: A multi-core optical fiber connection device comprises a first multi-core optical fiber connector and a second multi-core optical fiber connector. The first multi-core optical fiber connector comprises a first joint unit. The second multi-core optical fiber connector comprises a second joint unit. The second contact receptacle unit comprises a movable jacket and a movable ring. As long as the movable ring is pulled, the first joint unit is pushed by the movable jacket so that the first multi-core optical fiber connector and the second multi-core optical fiber connector are separated from each other, which achieves the effect that the first multi-core optical fiber connector and the second multi-core optical fiber connector are quickly connected with each other and separated from each other by one-hand operation.

Abstract: An optical apparatus comprises a first arm comprising a first optical waveguide configured to propagate a first optical signal, and a first thermo-optic (TO) phase shifter arranged proximate to the first optical waveguide. The optical apparatus further comprises a second arm comprising a second optical waveguide configured to propagate a second optical signal, and a second TO phase shifter arranged proximate to the second optical waveguide. The optical apparatus further comprises a thermal bridge arranged between the first TO phase shifter and the second TO phase shifter.

Abstract: The present disclosure provides a method and system including a non-confocal microscope with an attached imaging fiber optic for direct and real time visualization of mammalian microscopic structures for diagnostic and therapeutic uses.

Abstract: Low profile optical fiber connectors comprising a ferrule, a plug frame configured to receive the ferrule, and an outer housing configured to receive the plug frame. The outer housing may be configured to protrude less than about 2 mm from one end of an adapter when the low profile optical fiber connector is inserted into the adapter. The connector may include a boot sized such that the boot protrudes from the end of the adapter by less than about 15 mm.

Abstract: The present invention discloses an optical fiber connector, comprising: a housing, a ferrule installed within said housing; an end sleeve, connecting to the rear end of said housing; and an optical cable clamp, installed by insertion within said end sleeve, being provided for the purpose of clamping an optical cable. Said optical cable is secured within said optical cable clamp, and after said optical cable clamp is inserted and secured within said end sleeve, the optical fiber of said optical cable is inserted within said housing and butt-joined with the embedded optical fiber within said ferrule. As a result of this, before the butt-joined optical fibers are locked in, the optical cable has already been secured within the optical cable clamp and fixed to the connector housing. Therefore, the butt-joined optical fibers cannot be separated due to the effects of unexpected pulling force, thus ensuring the optical fiber of the optical cable reliably abuts the embedded optical fiber.

Abstract: Implementations of the present disclosure involve a cable terminator and/or method of using a cable terminator for non-operably securing a network cable at a destination port on a network device. The cable terminator has a body that includes an insert portion and a receiving portion. The insert portion is shaped so that it may be inserted into a port on a network device, while the receiving portion is shaped to receive a network cable.

Abstract: Connector assemblies having an adjustable polarity are described. A connector assembly comprises a frame comprising a single housing having top and bottom frame components, first and second plug frames located within the housing, a first ferrule located in the first plug frame, a second ferrule located in the second plug frame, and a latch component attached to the top or bottom frame component, the latch component having at least one compression element. The latch component is configured to rotate around the housing when the at least one compression element is compressed to change the polarity of the connector assembly from a first polarity when the latch component is located at a first polarity position to a second polarity when the latch component is located at a second polarity position.

Abstract: A network jack assembly network connection identification system comprising an identifier receiving cavity extending inward from a surface of a plug body section of the jack and an identifier element designed for insertion into the identifier receiving cavity. The identifier receiving cavity is accessible through any of a sidewall, a top wall, a bottom wall, or a front wall of the plug body section. The cavity may include a lens enabling viewing of the identifier element. The identifier can be a partially or completely colored surface of the identifier element, a shaped feature of the identifier element, etc. The identifier can be a sheet of material, a pin, or any other suitable insertable component. In one variant, the identifier can be formed during installation by reshaping material designated therefore, such as a wax. Alternatively, the identification solution can be applied to a wall plate.

Abstract: A behind-the-wall optical connector includes a ferrule having an annular collar projecting outwardly from a section of the ferrule and a plug frame receiving the ferrule in a central bore thereof, the plug frame including one or more resiliently-biased latches for gripping the ferrule annular collar to retain the ferrule within the plug frame. The optical connector may be fabricated inexpensively due to the low number of components. An optional boot may be provided. An insertion tool for assembling the optical connector is also described.

Abstract: An optical transceiver includes a case, a support, a driving member, a fastening member and a restoring member. The support is disposed on outer surface of the case. The driving member is on the support. The driving member is movable in press direction. The fastening member includes a pivot shaft, a fastening portion and a pressed portion. The pivot shaft is between the fastening portion and the pressed portion. The pivot shaft is pivoted to the support. The pressed portion has a pressed point, and the press direction is not parallel to a virtual line passing through the pressed point and the pivot shaft. When the driving member is moved to press the pressed point, the fastening member is pivoted to in fastened position or released position. The restoring member and the pressed portion are located on the side of the pivot shaft away from the second fastening portion.

Abstract: Devices and methods for connecting optical fibers are provided. In some embodiments, connectors and adaptors for two-fiber mechanical transfer type ferrules are disclosed. In some embodiments, MT connectors, such as simplex, duplex, and quad micro-MT adaptors are disclosed. In some embodiments, MT adaptors, such as simplex, duplex, and quad adaptors are disclosed. In some embodiments, optical fiber cables that modularly coupled with at least one optical fiber connector, adaptor, and other optical fiber cable the cable is configured to provide a remote release from an adaptor receptacle.

Abstract: A termination for a fiber optic cable, includes an optical connector for a fiber optic member, a collar having a hollow interior in which at least part of the optical connector is positionable, and a retaining clip positionable with respect to the collar at a location to block exiting of the optical connector from the collar. A stop in the collar limits insertion of the connector in the collar. The termination may be assembled and installed in the field. A method of assembling a cable termination assembly, includes positioning at least part of a cable and connector in a hollow collar, and inserting a retainer clip through an opening in a wall of the collar in position to block withdrawing of the connector from one end of the collar. Additionally, a resilient cover is positioned on the collar to provide a watertight connection with another device with which the cable termination assembly may be attached. The method may be carried out to assemble and install the cable termination assembly in the field.

Abstract: A fiber optic connector includes a carrier unit and two insertion units. The carrier unit includes a carrier body that defines two spaced-apart receiving spaces extending therethrough. Each receiving space has an opening formed in one side opposite to the other receiving space. Each insertion unit is configured to have an optical fiber extending therethrough, and is removably inserted into a respective receiving space through the opening so as to be disposed in a first or second position. Each insertion unit is rotated 180 degrees to change its position from the first to the second position or vice versa for polarity reversal. A sleeve unit is removably sleeved on the carrier body and covers the openings of the receiving spaces when sleeved on the carrier body.

Abstract: Devices and methods for connecting optical fibers are provided. In some embodiments, connectors and adaptors for two-fiber mechanical transfer type ferrules are disclosed. In some embodiments, MT connectors, such as simplex, duplex, and quad micro-MT adaptors are disclosed. In some embodiments, MT adaptors, such as simplex, duplex, and quad adaptors are disclosed. In some embodiments, optical fiber cables that modularly coupled with at least one optical fiber connector, adaptor, and other optical fiber cable using a remote release are disclosed.

Abstract: A fiber optic adapter (736/836) includes a body configured to mate a first fiber optic connector (12) with a second fiber optic connector (50), the first and second fiber optic connectors (12,50) including latches (60) for mating with catches (771) of the adapter (736/836) for releasably engaging the first and second connectors (12,50) with the fiber optic adapter (736/836), wherein the latches (60) are configured to be unlatched from the catches (771) by direct contact with the latches (60). The adapter (736/836) includes a release mechanism (702/802) for allowing a user to release the latch (60) of at least one of the first and second fiber optic connectors (12,50) from the adapter (736/836) without directly contacting the latch (60) of the at least one of the first and second fiber optic connectors (12,50).

Abstract: A connector, a system, and a method provide a single interface at a device for power and optical inputs or outputs. A single interface at the DC source allows for a single connection to the power and optical signals from the splitter. The connector can be used at other locations needing both power and optical signal connectivity.

Abstract: A connector part of a subsea connector, in particular an ROV mateable subsea connector, adapted to be mated with a second part of the subsea connector. The connector part includes at least a first contact configured for engagement with a respective second contact of the second connector part for establishing a connection. The connector part has a damper unit. At least the first contact is mounted to the damper unit. The damper unit is configured to be activated by an engagement of the connector part with the second connector part and is further configured to delay the engagement of the first contact with the second contact of the second connector part during the engagement of the connector part with the second connector part.

Abstract: A fiber optical connector comprises at least one fiber optical connector and a receptacle. The least one fiber optical connector comprises an outer housing, an inner housing, a plurality of ferrules, a plurality of compressible springs, a plurality of optical fibers, a supporting seat and a rear supporting assembly. The rear supporting assembly comprises a rear supporting tube, a ring, a pipe and a sleeve. The plurality of ferrules are provided in the inner housing and the inner housing is provided with outer latching portions at two sides of the inner housing; the rear supporting assembly further comprises a clamping collar, the clamping collar is sheathed on an outer surface of a rear segment of the pipe. The receptacle is provided with mating tubes in which the ferrules of the at least one fiber optical connector are correspondingly inserted. With such a configuration, the number of ferrules provided inside a single SC connector of the optical fiber standard specification is increased.

Abstract: Disclosed is an optical multichannel transmission and/or reception module, in particular for high-bitrate digital optical signals, with a housing having multiple optical input ports and/or optical output ports and containing an electric assembly and an essentially flat opto-electric module connected electrically to the electric assembly. Multiple electro-optic transmission elements and/or multiple opto-electric reception elements are located on or in the opto-electric module. The opto-electric module has an optical coupling area on one of its surfaces that is connected to the respective first ends of multiple optical waveguides. The opto-electric module has multiple optic paths for optical connection of each first end of an optic waveguide with an associated electro-optic transmission element and/or an associated opto-electric reception element.

Abstract: Multi-fiber ferrules may be produced with tapered bodies and guide pin holes that have fluted internal surfaces with projections for engaging the guide pins, and channels for capturing any foreign material that may accumulate on or around the guide pins, thereby providing improved consistency in fiber connections during mating of the ferrules.