Abstract: An optical transmitter includes an optical device, a wiring board including a first main surface and a second main surface, the optical device being mounted at a position closer to the second main surface than to the first main surface, a holding member fixed to the wiring board, at a position closer to the first main surface than to the second main surface, and an optical fiber inserted into a through hole of the holding member, where the wiring board includes a wiring pattern of a wiring layer sandwiched between an upper insulating layer and a lower insulating layer, and further includes an opening from which an upper surface and a lower surface of the wiring pattern are exposed, and an end surface of the optical fiber is in contact with the upper surface, and an external electrode of the optical device is bonded to the lower surface.

Abstract: A 3D printing system includes a 3D printer configured to receive as input a coated or un-coated optical fiber, to coat the optical fiber in the case of an input un-coated optical fiber, to treat an outer coating of the coated optical fiber, and to precisely output the coated optical fiber onto a specific location on a substrate such that the coated optical fiber is securely attached to the substrate via the treated outer coating. The 3D printer has a nozzle head that includes treating element for treating, such as heating or curing, the outer coating of the coated optical fiber. The 3D printer also includes a movement mechanism, such as an XYZ gantry, coupled to the nozzle head such that the nozzle head can be precisely moved relative to the substrate for well controlled placement of the treated coated optical fiber on the substrate.

Abstract: An optical network comprises a fiber distribution cable and a terminal assembly. The terminal assembly receives a plurality of optical fibers from the fiber distribution cable and distributes one or more individual fibers to one or more single fiber bare-fiber holders that hold and protect each single fiber prepared and configured for splicing via an individual splicing element. The splicing element includes an alignment mechanism having a base plate and a clamp plate. At least one of the base plate and clamp plate is formed from a silica material and at least one of the base plate and clamp plate includes an alignment groove or channel configured to receive the first and second optical fibers in an end-to-end manner. The splice element also comprises an optical adhesive disposed in at least a portion of the alignment groove, wherein the optical adhesive is curable via actinic radiation.

Abstract: An optical connector attached to a plurality of buffered optical fibers each including: a bare optical fiber; and a tube in which the bare optical fiber is inserted in. A multi-fiber optical connector is connected to first ends of the buffered optical fibers, and a plurality of single-fiber optical connectors are respectively connected to second ends of the buffered optical fibers. The multi-fiber optical connector includes: a ferrule fixed to ends of the bare optical fibers; a connector housing that houses the ferrule therein; and a tube fixing portion that fixes the tubes to the connector housing. The buffered optical fiber has a bare fiber fixing portion in which the bare optical fiber and the tube are fixed at a location closer to the ferrule than the tube fixing portion within the multi-fiber optical connector.

Abstract: Assemblies, optical connectors, and methods for forming fiber arrays using laser bonded optical fibers are disclosed. In one embodiment, a method of forming a fiber array includes placing an optical fiber on a surface of a substrate, directing a laser beam into the optical fiber disposed on the surface of the substrate, melting, using the laser beam, a material of the substrate to create a first laser bond zone between the optical fiber and the surface of the substrate, applying an adhesive to the optical fiber and the substrate to create an adhesive bond zone between the optical fiber and the surface of the substrate, and cutting the optical fiber and the substrate to create a first section of the fiber array and a second section of the fiber array.

Abstract: A heat-dissipation package for use with an optical fiber includes a base, a cover, and a hollow sleeve. The base includes an upper surface, a lower surface, and a groove embedded in the upper surface, the groove having a generally U-shaped cross-sectional shape. The cover is positioned on the upper surface of the base. The sleeve includes a cylindrical inner surface and an outer surface with a first portion which has a generally U-shaped cross section and a second portion which has a generally planar cross section such that edges of the planar cross section contact an open end of the U-shaped cross section. The first portion of the outer surface of the sleeve is positioned in the groove and the second portion of the outer surface of the sleeve is in contact with the cover. The sleeve is configured to encapsulate a heat-generating section of the optical fiber.

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 a receptacle hook and a housing with an opening that accommodates the receptacle hook in a flexed position as the optical connector makes connection with the mating receptacle by introducing the receptacle hook into an optical receptacle hook recess.

Abstract: An optical fiber sensor can be used to measure pressure with high sensitivity and fine resolution. As a cavity at the end of the sensor expands or contracts, the spectrum of a beam reflected from the end of fiber shifts, producing a change linked to pressure exerted on the sensor. Novel aspects of the present inventive sensor include the direct bonding of a silica thin film diaphragm to the optical fiber with localized or confined heating and a uniform thickness of the diaphragm. The resulting sensor has a diameter that matches the diameter of the optical fiber. Because the sensor is all silica, it does not suffer from temperature-induced error. In addition, the sensor can be very sensitive because the diaphragm can be very thin; it can also make highly repeatable measurements due to its very uniform thickness.

Abstract: An optical module to receive Rx-light from a single optical fiber and to transmit Tx-light to the single optical fiber is disclosed. In the optical module, the Rx-light enters a photodiode (PD) via a shortest path within a coupling block that provides surfaces constituting the path. The Tx-light emitted from a laser diode (LD) travels around a WDM filter within the coupling block. Both the Rx-light and the Tx-light enter the WDM filter at an acute angle. The lens to concentrate the Rx-light on the PD and to collimate the Tx-light is precisely aligned with respective devices mounted on a printed circuit board (PCB).

Abstract: The present invention discloses an alignment system for calibrating a position of an optical fiber (30) in a bore (31) of a ferrule (20), comprising: a calibration ferrule (200) having an alignment guide hole (201) formed therein; an alignment guide element (100) for calibrating a center position of a guide hole (21) of the ferrule, so that a center of the guide hole (21) of the ferrule (20) is aligned with a center of the alignment guide hole (201); a fiber core alignment element (300) comprising a fiber core (302) having a center positioned at a theoretical center relative to a positioning reference defined by the center of the alignment guide hole (201); an optical vision system for identifying a center position of a fiber core (32) of the optical fiber (30) and the center position of the fiber core (302) of the respective fiber core alignment element (300); and a controlling and moving system for actively adjusting the position of the optical fiber (30) in the bore (31) of the ferrule (20) under the guide

Abstract: A fiber coupling device comprising a mounting substrate, at least one optoelectronic and/or photonic chip and at least one first fiber coupling element for coupling an optical fiber to the fiber coupling device is disclosed. The optoelectronic and/or photonic chip has a main surface and comprises an optoelectronic and/or photonic active element couplable to a fiber end-piece of a respective optical fiber. The fiber coupling device further comprises at least one second fiber coupling element which is designed to contact and/or engage with a fiber end-piece of an optical fiber and which is mounted to the main surface of the at least one optoelectronic and/or photonic chip in a position aligned relative to the active element.

Abstract: An optical ferrule and an optical connector are provided, which make it possible to reduce the labor required for an adhesive wiping operation even when the optical ferrule is small-sized. A first adhesive filling recess 113 is equipped, which is formed at an outlet of an optical fiber hole 112 so that a forward end of a bare fiber 120, which is positioned by the optical fiber hole 112, is allowed to abut against an inner wall 113w opposed to the outlet, and the bare fiber 120 is adhered and fixed in a resultant state by means of an adhesive 131 with which the recess is filled, wherein the first adhesive filling recess 113 is provided with adhesive accommodating recesses 115, 117 which are shallower than the first adhesive filling recess 113 and are disposed continuously with the first adhesive filling recess 113.

Abstract: A cassette assembly which holds at least two electrical plugs which typically are connected to digital signal carrying cables. In one example, six of these plugs are positioned within a cassette, and are arranged in two rows of three plugs each for ease in connecting the plugs simultaneously to similarly arranged switch port jacks. A lever pivotally connected to the housing, when rotated, causes the release latch of the plugs held within the cassette to move from a locked to an unlocked position to simultaneously remove all of the plugs from the jacks to which they are connected.

Abstract: Fiber feedthrough device (50), for forming a hermetic seal around optical fibers in a flat fiber group (60) with a group width. The device comprises a slotted member and a base (62). The base defines a hole (65) that extends entirely through the base along a feedthrough direction (X), and is adapted to accommodate the slotted member. The slotted member (52) defines first and second surfaces (53) on opposite sides associated with the feedthrough direction, and a side surface (55, 56) facing transverse to the feedthrough direction. The slotted member comprises a slot (58), which extends along the feedthrough direction through the slotted member, and opens into the first and second surfaces and into a longitudinal opening (59) along the side surface. The slot extends transversely into the slotted member up to a slot depth at least equal to the fiber group width.

Abstract: An optical transceiver includes a main board, a fiber joint, a circuit board, a transfer board, metal traces, photoelectric elements, a lens set, a connection base, and an amplifier. The fiber joint is coupled to the lens set and connection base for positioning plural optical fibers. The connection base is coupled to the main board, and the circuit board is electrically connected to the main board. The transfer board is disposed between the fiber joint and circuit board. Each of the metal traces is arranged on both of two neighboring surfaces of the transfer board. The photoelectric elements are respectively coupled to metal traces on the surface of the transfer board facing the fiber joint, and axially aim to the optical fibers, respectively. The amplifier electrically connects the circuit board and the photoelectric elements via the metal traces.

Abstract: A monolithic optical element and system is used for collimating or focusing laser light from or to optical fibers. The optical fiber terminates in a tip that directly abuts against the first surface of the optical element. The optical element may provide a collimation or focusing function depending upon whether the abutting fiber delivers light for collimation or receives focused light from a collimated beam. The optical element may be a standard or modified barrel or drum lens, with the first and second surfaces being convex curved surfaces having the same or different radii of curvature. The end of the optical element to which the fiber abuts may have a diameter to match the inner diameter of a ferrule for positioning the fiber. A pair of the elements may be used for collimation and focusing in a Raman probehead or other optical detection system.

Abstract: A wavelength-multiplexing optical communication module includes: a substrate; a plurality of light sources on the substrate; a plurality of joint materials separately disposed on the substrate at positions respectively corresponding to the plurality of light sources; and a plurality of optical components fixed on the substrate by means of the plurality of joint materials respectively, wherein the substrate includes a plurality of forming portions which respectively form peripheries of the plurality of joint materials into shapes of circles or regular polygons having an even number of vertices.

Abstract: A fiber optic ferrule includes a body extending from a first end to a second opposite end, with the body including an axial passage extending between the first and the second ends. The axial passage includes a first diameter portion having a diameter of at least 125 microns, a second diameter portion having a diameter of at least 250 microns and less than a diameter of a buffer, and a smooth and continuous transition between the first and the second diameter portions. The second diameter portion is positioned between the first diameter portion and the second end. The axial passage further defines a tapered shape at the second end extending inward from the second end toward the second diameter portion. In certain embodiments, another smooth and continuous transition can be provided between the taper shape and the second diameter portion. In certain embodiments, the axial passage is smooth and continuous between the first and the second ends of the body. A hub holds the ferrule.

Abstract: A fiber gripper component includes a fiber receiving recess which extends from a first surface of the fiber gripper component toward a second surface of the fiber gripper component. The fiber receiving recess extends from a front face to a rear face. The fiber receiving recess has a fiber receiving surface which is positioned between the first surface and the second surface. A plurality of resilient fiber receiving grooves extend from the fiber receiving surface toward the second surface. The resilient fiber receiving grooves have a width which is less than an outer-diameter dimension of mating optical fibers to provide a press fit of the optical fibers into the resilient fiber receiving grooves. The fiber gripper component is molded with tolerances in the submicron range to maintain part functionality to allow automatable fiber assembly.

Abstract: A method for fabricating an optical transmitting apparatus includes steps of: preparing a temporary assembly including a stub device having an optical fiber, a magnetic guide member with a hole, and a holder, an optical connector, and an magnetic alignment member extending in a direction of an axis; applying a magnetic force to the alignment member of the temporary assembly with a magnet device of an electromagnet or a permanent magnet; carrying out optical alignment of the stub device with an optical device by active alignment, the stub device being optically coupled to the optical connector, and; separating the optical connector and the alignment member apart from the stub device. The alignment member is disposed in the hole of the stub device and a guide hole of the optical connector in the temporary assembly such that the alignment member aligns the stub device with the optical connector.

Abstract: A metal sheet laser welding clamp comprising a laser wavelength transparent body having a laser welding portion, the laser welding portion including an upper solid portion for transmitting laser wavelengths to a lower cavity portion for interfacing with a top metal sheet within a stack of metal sheets during a laser welding operation.

Abstract: An optical module is disclosed, which includes a substrate and an optical fiber bench attached to the substrate. The optical module also includes one or more optical fibers, each having an end placed on the optical bench. One or more optical devices are attached to the optical bench and in optical communication with the one or more fibers, respectively. An optical fiber alignment block is attached to the optical fiber bench with the one or more optical fibers therebetween. The optical fiber alignment block includes a reflecting surface that deflects an optical path between the one or more optical fibers and the one or more optical devices.

Abstract: An automatic light control switch includes: a housing configured to receive an optical fiber; a built-in light sensor located in the housing and configured to directly detect light through the housing; an external light sensor located in the housing and shielded from light, the external light sensor being configured to be coupled to the optical fiber and to detect light transmitted by the optical fiber; and a drive controller configured to: determine, automatically, a usage condition as one of an indoor condition and an outdoor condition in accordance with a condition signal; in response to determining that the usage condition is the indoor condition, disable the built-in light sensor and enable the external light sensor; and in response to determining that the usage condition is the outdoor condition, enable the built-in light sensor and disable the external light sensor.

Abstract: A collimator device and a collimator lens array for an optical circuit switch are provided. The collimator includes a fiber array including multiple optical fibers disposed in a hole array. An optical lens array is aligned and coupled to the fiber array. A spacer is disposed between the fiber array and the optical lens array and provides substantially uniform spacing between lenses in the optical lens array and corresponding fibers in the fiber array. Multiple pads are positioned along edges of a surface of the spacer facing the optical lens array defining a first separation gap between the spacer and the optical lens array. A first epoxy bonds the spacer to the optical lens array, and a second epoxy bonds the spacer to the fiber array. The optical lens array includes a glass substrate having a first surface defining lenses in a two-dimensional array.

Abstract: An optical module that implements an MMI device including an optical hybrid primarily made of semiconductor material is disclosed. The MMI device, which has a rectangular plane shape and includes multi-mode couplers, is mounted on a carrier. The carrier provides a step extending in a whole lateral width of a top surface thereof, where the step makes a gap against the MMI device in an area where the MMI couplers are formed.

Abstract: An optical transceiver includes a main board, a fiber joint, a circuit board, a transfer board, metal traces, photoelectric elements, a lens set, a connection base, and an amplifier. The fiber joint is coupled to the lens set and connection base for positioning plural optical fibers. The connection base is coupled to the main board, and the circuit board is electrically connected to the main board. The transfer board is disposed between the fiber joint and circuit board. Each of the metal traces is arranged on both of two neighboring surfaces of the transfer board. The photoelectric elements are respectively coupled to metal traces on the surface of the transfer board facing the fiber joint, and axially aim to the optical fibers, respectively. The amplifier electrically connects the circuit board and the photoelectric elements via the metal traces.

Abstract: A monolithic optical element and system is used for collimating or focusing laser light from or to optical fibers. The optical fiber terminates in a tip that directly abuts against the first surface of the optical element. The optical element may provide a collimation or focusing function depending upon whether the abutting fiber delivers light for collimation or receives focused light from a collimated beam. The optical element may be a standard or modified barrel or drum lens, with the first and second surfaces being convex curved surfaces having the same or different radii of curvature. The end of the optical element to which the fiber abuts may have a diameter to match the inner diameter of a ferrule for positioning the fiber. A pair of the elements may be used for collimation and focusing in a Raman probehead or other optical detection system.

Abstract: An optical connector has an optical waveguide slit and a pass-through hole. The optical waveguide slit is a hole that extends from an insertion surface of a connector body into the connector body. The optical waveguide slit accommodates a sheet-like optical waveguide whose tip abuts against a slit bottom. The pass-through hole is provided near the slit bottom, and passes through the top surface of the connector body and the top surface of the optical waveguide slit.

Abstract: The present disclosure relates to a clamp sleeve for a bundled fiber cable. The clamp sleeve includes a first actuating arm, a second actuating arm, and a hinge connecting the first actuating arm and the second actuating arm. The first actuating arm includes a first protuberance, a second protuberance, and a third protuberance, such that a slot forms between each protuberance. The second actuating arm a fourth protuberance, a fifth protuberance, and a sixth protuberance with a slot formed between the fourth, fifth, and sixth protuberances.

Abstract: Provided is an apparatus for measuring convergence and ceiling subsidence using a fiber bragg grating sensor. The apparatus includes a plurality of unit-fiber bragg grating sensor modules having a predetermined length and sequentially connected to each other, where each of the sensor modules comprises: a fiber bragg grating stain sensor installed in a protective tube to sense a variation of a length; an installing member installed in parallel to one side of the protective tube; a fiber bragg grating angle displacement sensor mounted on the installing member to measure angle displacement; bases provided at both ends of each sensor module to connect adjacent sensor modules to each other; and a fixing member and a fixing unit to fix both ends of the protective tube and the installing member to the bases, respectively. Each of the sensor modules continuously measures two-dimensional or three-dimensional convergence and ceiling subsidence.

Abstract: An opto-electric (OE) module having a front and back orientation and comprising a connector having a front end configured to mate with a connector, an optical interconnect comprising an optical conduit with first and second ends, the first end being terminated by at least one first ferrule, the first ferrule being disposed in the connector in a non-biased state, and the second end being optically coupled to at least one opto-electric device (OED), wherein the optical interconnect is not configured to bend to accommodate distance variations between said first ferrule and said OED, a cover being attached to the connector and having an interior, a circuit board disposed in the interior and having an electrical interface configured to connect to a daughter card, and the opto-electric device (OED) attached to the circuit board and optically connected to the second end.

Abstract: A memory module has a memory mounted thereon. A support plate supports a circuit board. The circuit board is located facing and separated from the support plate. The circuit board has a first contact. A holder has a recessed housing portion and a first engagement portion. The housing portion is formed to internally house the memory module. The first engagement portion is provided to be inserted into an opening and engage with the opening. The holder is configured to be fixed to the support plate in an attitude in which the housing portion is open toward the circuit board, by the first engagement portion engaging with the opening. A lid is mounted on the holder by being inserted into the housing portion. A conductive portion is provided on the lid. The conductive portion is configured to electrically connect the memory module to the first contact of the circuit board.

Abstract: A cable breakout assembly is provided, including a feeder cable, a breakout structure having a first end threadedly engaged with a cable nut having a single-port cable gland through which the feeder cable extends, a central conduit which houses the sections of the feeder cable passing there through, and an opposed second end threadedly engaged with a cable nut having a multi-port cable gland, whose number of ports corresponds to the number of splices of the feeder cable. A plurality of environmentally sealed, flexible conduits are provided, each having a first end that interfaces with and extends from a respective port of the multi-port gland, and a second end adapted to interface with an external device, wherein each flexible conduit houses a respective spliced section of the feeder cable therein.

Abstract: An optical fiber connector for positioning a number of optical fibers is provided. The optical fiber connector includes a main body and a pressing block. The main body defines an assembling recess and a number of positioning grooves defined in a bottom surface of the assembling recess. The positioning grooves each correspond to an optical fiber. An end of each optical fiber is received in a corresponding positioning groove, and the pressing block is received in the assembling recess.

Abstract: Aspects of the present invention include an optical fiber routing mat for routing optical fibers. The optical fiber routing mat includes a first layer of material and a second layer of material. A surface of the first layer of material is adhesively coupled to a surface of the second layer of material. The optical fiber routing mat includes one or more optical fibers disposed between the first layer of material and the second layer of material. The one or more optical fibers are bent to a radius at least large enough to prevent damage to the one or more optical fibers.

Abstract: A fiber optic transceiver that is compatible with packaging into standard semiconductor packages and for SMT packaging, using materials and fabrication procedures that withstand solder assembly processes. The SMT package can have electrical contacts on the exterior of the package for creating electrical conduits to a substrate, such as a PCB, interposer, or circuit card within a larger assembly. The fiber optic transceiver can be of a non-SMT package configuration, being formed with electrical connection technology that allows direct connection to a substrate with electrical wiring, such as a PCB, interposer, or circuit card within a larger assembly. The fiber optic transceiver may have solderballs, metal posts or other electrical conduit technology that allows direct electrical connection to the substrate.

Abstract: An apparatus for providing single mode optical signal coupling between an opto-electronic transceiver and a single mode optical fiber array takes the form of a lens array and a ferrule component. The lens array includes a plurality of separate lens element disposed to intercept a like plurality of single mode optical output signal from the opto-electronic transceiver and provide as an output a focused version thereof. The ferrule component includes a plurality of single mode fiber stubs that are passively aligned with the lens array and support the transmission of the focused, single mode optical output signals towards the associated single mode optical fiber array.

Abstract: A microstructure optical adapter or tip according to the present disclosure may incorporate precision micro structure optical components engaging the input or output end of light energy delivery devices for customized light delivery of the light energy. The incorporation of precision micro structure optical components in injection molded plastic or glass parts will allow for inexpensive modification of the output light while also serving to protect the end of the illumination device. The micro structure optical components may also be incorporated in an adapter to tailor the light energy to the subsequent device.

Abstract: An apparatus to attach a fiber block to a silicon waveguide. The apparatus includes a holder base holding a portion of an array of optical fibers aligned optically in multiple slots in parallel. The apparatus further includes a holder cap combined with the holder base for fixing the portion of the fibers and leaving the fibers free with arbitrary length beyond a first edge of the holder base but keeping only additional second length of the fibers beyond a second edge of the holder base with fiber ending facets at the second length. Additionally, the apparatus includes a silicon photonics waveguide chip including an attachment section connected to a waveguide section. The attachment section includes multiple grooves laid in parallel for respectively attaching with the second length of the fibers so that the fiber ending facets are coupled to multiple waveguides formed in parallel in the waveguide section.

Abstract: Organizer tray including a base wall and a receiving wall that is coupled to the base wall. The base and receiving walls extend parallel to each other along a lateral axis. The receiving wall extends away from the base wall along an elevation axis that is perpendicular to the lateral axis such that the base and receiving walls define a circuit channel. The receiving wall has a curved shape. The base and receiving walls are shaped to hold a flex circuit assembly within the circuit channel, in which the flex circuit assembly includes a fiber-routing substrate and corresponding segments of optical fibers that extend within the fiber-routing substrate. The base and receiving walls are configured to hold the fiber-routing substrate such that the fiber-routing substrate satisfies a bend radius of the optical fibers.

Abstract: Embodiments of the present disclosure are directed toward techniques and configurations for an apparatus with an optical connector. In one embodiment, the apparatus may include an optical connector having a cage to receive an optical fiber cable to connect the apparatus with another apparatus. The cage may include first and second sides and a face that mates the first and second sides. The face may comprise an optical interface to optically connect tips of the optical fiber cable and the other apparatus. The cage may further include a cavity having a first portion formed substantially in the face to receive the optical interface, and a second portion that extends into one of the first or second sides to provide an opening to enable application of an adhesive material to the tips of the cable, to fixably connect the tips with the optical interface. Other embodiments may be described and/or claimed.

Abstract: An optical fiber fastening device holds an optical fiber which includes a core and a cladding layer surrounding the core. The cladding layer includes strips peeled from the core. The optical fiber fastening device includes a clamping member and a fastening sleeve. The clamping member includes a first and a second clamping portion buckled together to clamp the optical fiber, with one including at least one locating rod configured for being wrapped around by the strips, and the other including at least one locating hole receiving the at least one locating rod. The fastening sleeve sleeves over and holds the first and the second clamping portion together.

Abstract: An optical bus of an integrated circuit comprises: a polymer waveguide, a micromirror, and an optical coupler. The polymer waveguide is disposed in a via formed through at least one die layer of the integrated circuit comprising an active circuit. The micromirror is disposed adjacent to the via and optically coupled to the polymer waveguide. The optical coupler is connected to the polymer waveguide to couple the active circuit to the optical bus. A stacked integrated circuit is described comprising such an optical bus. A method of fabricating a rear 45° micromirror on a silicon substrate that can be used in the optical bus is also described. Furthermore, alignment/lock mechanisms for use in a stacked integrated circuit comprising first and second silicon substrates are described.

Abstract: A splice chip includes a base, separation members extending upwardly from the base to define a plurality of rows, and latching fingers extending upwardly from the base to further define the rows. At least one of the rows includes at least a first latching finger, a second latching finger, and a third latching finger. The third latching finger is shorter than the first and second latching fingers. The second latching finger is shorter than the first latching finger. The row also may include a fourth latching finger that is the same height as the first latching finger.

Abstract: A fiber optic interface for a fiber optic ribbon includes a homogeneous flexible body comprising one or more grooves defined therein, each groove configured to receive a corresponding filament of the fiber optic ribbon. Each groove is further configured to receive an adhesive to attach the groove to a first portion of a corresponding filament while leaving a second, opposing portion of the corresponding filament and lateral side portions of the corresponding filament between the first and second portions substantially accessible for connection to a mating component. An overflow port for each groove provides an opening extending from a corresponding groove through the body of the interface for draining excess adhesive from the groove.

Abstract: A solar concentrator comprising a transparent optical material including a first light coupling portion having an outer end and an inner end tapered so that it converges from the outer end towards the inner end; a first facet formed at the outer end and arranged to reflect light along the first light coupling portion; a first primary concentrator element arranged to focus light onto the first facet; a second light coupling portion having an outer end and an inner end tapered so that it converges from said outer end towards said inner end; a second facet formed at the outer end of the second light coupling portion and arranged to reflect light along said portion the second facet vertically overlapping the first facet; a second primary concentrator element arranged to focus light onto the second facet; a common light guide portion in optical communication with said inner ends of the first and second light coupling portions and arranged to transmit said radiation therethrough; wherein a greatest vertical thickne

Abstract: A package for an arcuate planar lightwave circuit (PLC) chip includes a heater plate coupled to a base by a thick and soft support layer. The arcuate PLC is attached to the heater plate by soft adhesive. A hard adhesive is applied to a multi-waveguide end of the arcuate PLC, to additionally strengthen the attachment of the arcuate PLC to the heater plate. The structure allows the mechanical stress due to fiber pull/shock/vibration to be dissipated in the support layer without introducing large wavelength shifts in the arcuate PLC. The support layer also serves as a heat insulator, facilitating uniform heating of the arcuate PLC.

Abstract: Embodiments of the present invention relate to fiber optic hydra cable assemblies and components thereof. In an embodiment, the present invention is a fiber optic cable transition which includes a front housing having a front opening, a rear opening, and an internal wall positioned inside of the front housing. The fiber optic cable transition also includes a front boot having a distal end, a proximal end, and a flange, the front boot being positioned at least partially inside the front housing such that the flange abuts the internal wall. The fiber optic cable transition also includes a rear housing having a distal end and a proximal end, where the rear opening of the front housing is joined to the proximal end of the rear housing.

Abstract: Fiber optic cables seal and/or strain relief members and related assemblies and methods are disclosed. In one embodiment, an elongated member is provided that facilitates providing sealing and/or strain relief of a portion of multiple fiber optic cables not enclosed within a common outer cable jacket or sheath when disposed through the opening of the fiber optic terminal. In one embodiment, the elongated member includes a sealing portion configured to facilitate sealing of a fiber optic terminal opening when the multiple fiber optic cables are received in the sealing portion and the elongated member is disposed through the opening of the fiber optic terminal. In another embodiment, the elongated member includes a strain relief portion on a second end configured to receive and provide strain relief to the multiple fiber optic cables disposed inside the fiber optic terminal, when the elongated member is disposed through the fiber optic terminal opening.

Abstract: A multi-optical fiber connector module is provided with an unfilled plastic cover that is used to secure the ends of a plurality of optical fibers at precise locations within the connector modules. The cover has deformable features that permanently deform when the cover is secured to a housing of the connector module. The permanent deformations are caused by forces that are exerted on the deformable features by respective unjacketed optical fibers when the cover is secured to the module housing. When the features deform, they partially wrap about the respective unjacketed optical fibers such that the respective fibers are pinned between the respective deformed features and the respective V-shaped grooves of the module housing. This contact between the deformed features, the respective unjacketed optical fibers and the respective V-shaped grooves maintains the respective unjacketed optical fibers in precise locations along respective optical pathways of the connector module.