Abstract: An optical ferrule comprising: (a) a body defining an end face; (b) one or more channels extending from said end face through said body, each channel adapted to receive an optical fiber; and (c) first and second alignment pin channels defined in said end face, each alignment pin channel having a center point, said center points being disposed along a first axis, said first alignment pin channel having a first cross section essentially the same as that of an alignment pin and being adapted to receive said alignment pin, said second alignment pin channel having a second cross section elongated along said first axis.

Abstract: An optical digital audio connector including a ferrule radially disposed over an optical fiber, an outer shell, having a first end and a second end, disposed over the ferrule, the outer shell having an extension extending from the first end of the outer shell, wherein the outer shell and extension have at least one axial slot, the at least one axial slot starting proximate the second end of the shell and axially extending through the outer shell and extension to facilitate radial movement of the outer shell and the extension, and a latching feature structurally integral with the extension, wherein the latching feature is a ramped surface forming a peak, the peak raised a distance from the outer surface, is provided. Furthermore, an associated method is also provided.

Abstract: A waveguide connector includes a ferrule with a number of waveguides inserted thereinto. The ferrule includes a front mating surface, a rear surface, front and rear passageways extending through the front and the rear mating surfaces, respectively. The front and the rear passageways are in communication with each other while the front passageway is thinner than the rear passageway. The waveguide each includes a number of cores and a cladding layer enclosing the cores. The front part of the cladding layer is of rectangular shape and includes four peripheral surfaces which are so limited by four inner surfaces of the front passageway, respectively, so as to precisely position the waveguides.

Abstract: A method to assemble a pig-tailed optical module and an arrangement thereof are disclosed. The method includes a step to recover the optical coupling efficiency between the optical device in the optical module and the pig-tailed fiber. The recovering method includes a step to iterating the YAG laser welding at a point not points axially distributed with a constant pitch as slightly rotating the optical module around the optical axis in a direction and an opposite direction depending on the improvement and the degradation of the optical coupling efficiency.

Abstract: A fiber optic cable assembly includes a fiber optic cable with one or more optical fibers attached to a housing. The housing includes a connector housing for a connector, a furcation housing for a furcation, and a splice housing for a mid-span cable splice. The furcation housing and the splice housing include a crimp body. The crimp body has a compression area and at least one hoop about the compression area defining a crimp zone. A crimp band is arranged for engaging the crimp zone and including an indentation defining a compression surface and a rib defining a rib interior. The crimp band and the crimp body cooperate to grip the strength element and resist cable pull off forces. A method of making the fiber optic cable assembly is also disclosed.

Abstract: The present invention relates to a positioning means for a fibre optic connector assembly, a fibre optic connector assembly and a fibre termination unit comprising the positioning means through which manufacturing tolerances can be absorbed to provide an improved optical interconnection with a high signal transmission rate. The positioning means (1) comprises a receiving means (5) for receiving one of a jack assembly or plug assembly (2) and a stationary support (6) supporting said receiving means (5), wherein the receiving means (5) is displaceable to a certain extent relative to the stationary support (6) at least along one direction other than a connection direction for optically interconnecting the optical fibers allowing an alignment of the receivable jack or plug assembly (2) along the direction transversal to the connection direction. A spring loaded element (8) resiliently urges said receiving means (5) away from the support (6) in one embodiment.

Abstract: A fiber optic connector includes a front housing having sidewalls each defining a slot and a rear insert with a pair of locking flanges extending radially away, the locking flanges configured to snap-fit into the slots, each locking flange defining a front face and a rear face, the radially outermost portion of the rear face defining an edge, the edge being the rearmost extending portion of the locking flange. Another fiber optic connector includes a front housing defining a front opening at a front end, a circular rear opening at a rear end, and an internal cavity extending therebetween. A rear insert including a generally cylindrical front portion is inserted into the front housing through the circular rear opening, the front portion defining at least one longitudinal flat configured to reduce the overall diameter of the generally cylindrical front portion configured to be inserted into the front housing.

Abstract: This high power optical connector is used at least on a light-receiving side of an optical fiber. The high power optical connector is provided with: a housing; a ferrule which is accommodated in the housing to retain the optical fiber; and a flange which is connected and fixed to the housing while being in contact with an end portion of the ferrule. The ferrule is made of a transparent glass; and the flange is made of a transparent material which transmits a light which propagates through the optical fiber.

Abstract: Provided is a duplex optical connector in which a pair of connector mounting portions of a holder includes a first abutment portion (first cylindrical surface) abuttable against a groove bottom surface of an annular groove provided at a proximal end of corresponding one of a pair of optical connectors from one side in a width direction, a second abutment portion (second cylindrical surface) abuttable against the groove bottom surface from another side in the width direction, and a widthwise movable region (W) which allows the corresponding one of the pair of optical connectors to move in the width direction between the first abutment portion and the second abutment portion with respect to the holder. With this, a pitch between the pair of optical connectors can be changed.

Abstract: A connector component for optical fibers has good dimensional accuracy and parallelism. The connector component includes a base material. The base material is provided with at least two holes for inserting and fixing optical fibers therein. The base material is made of quartz glass. Inner components are arranged for forming holes for inserting optical fibers in a die for forming an outer form of the connector component with a dimensional accuracy equal to or less than 2 ?m. Slurry is poured into the die, the slurry including quartz powder, a resin binder, a dispersant, water and a curing agent. The poured slurry is cured and heated under vacuum so as to vitrify the cured slurry to obtain the quartz glass.

Abstract: A waveguide connector includes a ferrule with a number of waveguides inserted thereinto. The ferrule includes a front mating surface, a rear surface, front and rear passageways extending through the front and the rear mating surfaces, respectively. The front and the rear passageways are in communication with each other while the front passageway is thinner than the rear passageway. The waveguide each includes a number of cores and a cladding layer enclosing the cores. The front part of the cladding layer is of rectangular shape and includes four peripheral surfaces which are so limited by four inner surfaces of the front passageway, respectively, so as to precisely position the waveguides.

Abstract: An optical fiber cable, includes at least one optical fiber and a cable connector at a cable end, and a removable cap removably couplable to a free end of the cable connector. The cap includes a recess adapted to receive and accommodate an anchor element of a cable pulling rope, and to retain the anchor element against traction when the pulling rope is tractioned.

Abstract: The present document describes an optical interconnect module for interfacing optical fibers. An optical interconnect module in accordance with an embodiment comprises a casing including a projection and an optical sub-assembly including an interlock portion for receiving the projection of the casing. The optical sub-assembly carries a plurality of optical fibers, and couples face to face with an optical cable assembly for aligning the corresponding fibers together. The optical cable assembly is usually provided in an optical cable connector, along with a spring which compresses when the optical cable connector is inserted in the optical interconnect module. The pressure provided by the spring is transmitted to the optical sub-assembly. The optical sub-assembly applies this pressure to the projection received in the notch thereof for maintaining a tight engagement with the optical cable assembly.

Abstract: An optical connector reduced in size and capable of reducing optical coupling losses when optical waveguides are connected to each other, and a method of manufacturing the same are provided. The optical connector comprises: an optical waveguide including cores for transmitting light, an under cladding layer provided under the cores, and an over cladding layer provided over the cores; and a ferrule section for optical connection provided in each end portion of the optical waveguide. Part of at least one of the over cladding layer and the under cladding layer lying in a location corresponding to each end portion of the optical waveguide is thick-walled to become the ferrule section for optical connection. A thin-walled part of the optical connector lying between the ferrule sections is an optical waveguide section. The optical connector requires no additional component as a ferrule, and is made small in size.

Abstract: Fiberoptic connector and adapter assembly includes a fiberoptic connector received within an adapter. The connector has a cover on the connector housing. The cover pivots between open and closed positions to expose or cover, respectively, a optical fiber contained within the connector. Longitudinal guides of the connector are received cooperating with longitudinal guides of the adapter to direct the connector into the adapter in a prescribed alignment. A cam pin is carried on the adapter to engage a cam pin receiving slot on the cover to urge the cover to the open position as the connector is inserted into the adapter.

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: Disclosed are fiber optic connectors including a holder for attaching a fiber optic cable to a fiber optic connector along with cable assemblies and methods for making the same. In one embodiment, the holder includes a first and a second cantilevered arm that are squeezed together when a sleeve is placed over the holder. Further, one or more of the cantilevered arm may include a plurality of teeth for “biting” into the cable jacket and providing a suitable fiber optic cable retention force. The fiber optic connectors, cable assemblies and methods disclosed herein are advantageous since they allow the craft to quickly, reliably, and easily attach a robust fiber optic cable to a connector, thereby providing a rugged solution for the craft.

Abstract: Receptacle ferrules with at least one monolithic lens system and fiber optic connectors using same are disclosed. Ferrule assemblies formed by mating plug and receptacle ferrules are also disclosed, as are connector assemblies formed by mating plug and receptacle connectors. The fiber optic connectors and connector assemblies are suitable for use with commercial electronic devices and provide either an optical connection, or both electrical and optical connections. The monolithic optical system defines a receptacle optical pathway having a focus at the receptacle ferrule front end. When a plug ferrule having a plug optical pathway is mated with the receptacle ferrule, the plug and receptacle optical pathways are optically coupled at a solid-solid optical pathway interface where light passing therethrough is either divergent or convergent, and where unwanted liquid is substantially expelled.

Abstract: A cable assembly (100) includes a first connector (1), a second power connector (2) arranged with the first connector in a side by side manner, and a cable (3). The first connector includes a first insulative housing (11), a set of terminals coupled to the first insulative housing for transmitting electrical signals, and an optical module (14) attached to the first insulative housing and stacked with the terminals for transmitting optical signals. The cable includes a set of first electrical wires (31) connecting with the first terminals, a plurality of optical fibers (32) connecting with the optical module, and a plurality of second electrical wires (33) connecting with the second power connector.

Abstract: A fiber assembly (1000) includes at least one fiber (300) including a horizontal section (32) extending along a front-to-back direction, a vertical section (30) extending along a up-to-down direction and a mediate section (31) connecting with the horizontal section and the vertical section; a housing (1) including a first housing piece (10) and a second housing piece (12) combined together to form a substantial ninety degrees arc shape positioning passage (120) therebetween to receive the mediate section (31), under the condition that the horizontal section and the vertical section are disposed perpendicular to each other.

Abstract: In accordance with the following description, an optical communication connector includes a ferrule having retractable alignment pins that are actuable between an extended position and a retracted position. For example, the connector may include an inner housing assembly having optical fibers and an outer housing positioned over the inner housing assembly. The outer housing is shaped to be removable from the inner housing assembly, which has a movable pin clamp mechanically coupled to alignment pins for aligning the connector with another connector. The pin clamp may be slid from a first position (corresponding to a male gender) to a second position (corresponding to a female gender). Separately or in combination with changing gender, the polarity of a communication connector may be changed due to its inclusion of an asymmetric polarity-changing feature that is actuable by an installer to change a polarity of the communication connector.

Abstract: The optical connector, comprising: a first plug having a first ferrule for holding a first multiple optical fiber; a second plug having a second ferrule for holding a second multiple optical fiber; a first housing on which the first plug is detachably fixed; a second housing which is detachably fixed on the first housing and on which the second plug is fixed in such a manner that each edge face of optical fibers of the first multiple optical fiber and each edge face of optical fibers of the second multiple optical fiber are mutually adjusted, and the first housing has a first ferrule positioning member for positioning the first ferrule in relation to the second ferrule.

Abstract: A fiber optic assembly comprising an adapter assembly defining an internal cavity, a first end for a receiving a first fiber optic connector, and a second end for receiving a second fiber optic connector, wherein the first and the second fiber optic connectors are dissimilar. A fiber optic connection comprising a first fiber optic connector comprising a connector housing, a first multi-fiber ferrule, and a clearance about an end face of the first multi-fiber ferrule for clearing a ferrule surround during connector mating, and a second connector that is a FOCIS 5 compliant MTP connector.

Abstract: Push-pull fiber optic connectors and cable assemblies having a latch that is actuated by a cam surface are disclosed. The fiber optic connectors include a ferrule and a housing having the latch. A shroud fits over a portion of the housing and allows the craft to grab the shroud and push the shroud and hence the fiber optic connector into a suitable adapter or the like. Likewise, the craft can grab the shroud and pull on the same to remove the fiber optic connector out of the adapter or the like. The cam surface is disposed on a decoupling member, wherein the decoupling member is attached to the shroud so the components can move together. Methods of making the push-pull fiber optic connector are also disclosed.

Abstract: There are provided an optical connector having one or more protruding portions protruding and one or more recessed portions depressed relative to a reference plane corresponding to a reference face of a coupling of a standard optical connector in a connecting end face of a coupling into which a housing receiving a ferrule is inserted, a connector adapter to which the optical connector can be inserted and coupled, an optical fiber line using the optical connector and the connector adapter to connect optical fibers, and an optical communication system.

Abstract: An optical connector comprises a housing, a regulating portion which is protrudes toward an inner surface of the housing, a ferrule which is secured to an optical fiber and which is accommodated inside the housing so as to be movable. The ferrule includes a base portion and a thinned portion that has a thickness smaller than that of the base portion. If the ferrule moves forward in the butt-connection direction, the regulating portion and the base portion approach each other, so that the regulating portion regulates the movement of the ferrule in the thickness direction. If the ferrule moves backward in the butt-connection direction, the ferrule reaches a position where the thinned portion faces the regulating portion, so that the movement of the ferrule in the thickness direction is not regulated by the regulating portion.

Abstract: A special plug connector is proposed for contacting a mating plug using a standard plug connector, such that the dimensions of the mating plug differ from this standard plug connector in both horizontal and vertical directions. This special plug connector has a plug connector housing with two bearing pins and a holding element for holding two respective ferrule housings. Firstly, the holding element is elastically connected by a first spring element to the plug connector housing. Secondly, the holding element having two arms, each of which has a corresponding elongated hole, is rotatable within a certain angular range about the bearing pins of the insert under the influence of a spring and is held on the plug connector housing, so that it is displaceable by a first displacement path axially to the ferrules under the influence of a spring.

Abstract: An interface converter is provided for mechanically and optically coupling a non-ruggedized fiber optic connector with a ruggedized adapter port. In a preferred embodiment, the interface converter attaches to an SC fiber optic connector and together form a converted fiber optic connector compatible with the ruggedized adapter port. In certain embodiments, a retractable release sleeve may be removed from the SC fiber optic connector prior to attaching the interface converter. In certain embodiments, the interface converter may be inserted into the ruggedized adapter port prior to being attached to the SC fiber optic connector.

Abstract: The present invention provides an optical fibre connector (1) having a fibre connector sub-assembly (21) and an outer connection sleeve (40), sub-assembly (21) having an optical fibre and an inner housing (20). The optical fibre is held within housing (20) along axis (5), and is terminated for optical connection to a mating connector along a connection direction (61). Sleeve (40) has a securing portion (50) and a connecting portion (48). Securing portion (50) is fixed to sub-assembly (21) so that sleeve (40) extends around sub-assembly (21). Connecting portion (48) has an inner surface that provides a socket (44) for receiving a corresponding portion of a mating connector along direction (61). Socket (44)'s inner surface has at least one rib that extends transverse to direction (61), connecting portion (48) being elastic such that the rib(s) may, in use, stretch over and engage with a corresponding feature of a mating connector.

Abstract: A re-terminable, no-crimp ST-type optical connector assembly includes a spring-loaded ferrule holder assembly and a reusable activation system for termination of the assembly. The optical connector can be terminated by a suitable cam activation tool. The connector includes a housing, such as a bayonet, matable to a mating adapter, a backbone retained within a rear of the housing, a ferrule holder provided within the backbone, and a cam provided between the ferrule holder and the backbone. The ferrule holder includes an alignment key exposed to mate with a cam activation tool to lock rotation of the ferrule holder relative to other connector components. The cam includes a cam activation cutout at a front face thereof that mates with a cam activation tool interface to enable rotation of the cam between de-activated and activated positions, the cam activation cutout also receiving the alignment key of the ferrule holder therethrough.

Abstract: An optical fiber adapter includes a housing, a hook member and an elastic body. The housing has an axial cavity defined by a first wall, a second wall, a third wall and a fourth wall. The hook member is positioned in the axial cavity which comprises a flange, a hollow cylinder and a pair of hooks. The hollow cylinder and hooks extends from one end of the flange and the hollow cylinder is positioned between the hooks. The elastic body is positioned on and around the hollow cylinder. When the optical fiber connector is inserted into the axial cavity of the optical fiber adapter, the ferrule will be inserted into the hollow cylinder and the elastic body will be in contact with inner walls of the inner housing of the optical fiber connector.

Abstract: An optical connector plug incorporates a coil spring to bias a shutter holding member to the front side of an axial direction with respect to a plug frame and minimizes the entire length. The plug has a housing that includes a grip member and a shutter holding member that move relatively in the axial direction and the plug frame has an extension state in which the grip member moves to the rear side of the axial direction of the shutter holding member and a reduction state in which the grip member moves to the front side of the axial direction of the shutter holding member. A biasing member that biases the shutter holding member to the front side of the axial direction with respect to the plug frame and a biasing member receiving member that is connected to the plug frame are provided.

Abstract: Provided is an optical connector including: a ferrule housing; a coupling, wherein the housing is insertable into the coupling; a coupling engagement member provided at a rear of the housing; and a boot formed to accommodate ant optical fiber therethrough and extending rearward from the coupling engagement member. The optical connector is moveable into a first position by pressing the boot in a forward direction, thus exerting a forward pressure on the coupling engagement member and into a second position by pulling the boot in a rearward direction, thus exerting a rearward pressure on the coupling engagement member. In the first position, the coupling engagement member abuts the housing, such that the forward pressure on the coupling engagement member is exerted on the housing. In the second position, the coupling engagement member engages the coupling such that the rearward pressure on the coupling engagement member is exerted on the coupling.

Abstract: An optical transmission module includes a stem, a semiconductor laser element mounted over the stem, a cap fixed to the stem and hermetically sealing the semiconductor laser element, and an optical isolator arranged on an optical path of light emitted from the semiconductor laser element. The cap includes a tubular body, one end side of which is fixed to the stem, and a light transmitting section located on the optical path while closing an opening on the other end side of the body, and fixed to the body so as to keep hermeticity with the body. The optical isolator is arranged inside an area hermetically sealed by the cap.

Abstract: According to at least one exemplary embodiment a ferrule, comprises: (i) a bore extending from a rear of the ferrule to a front of the ferrule, wherein the bore is sized to receive an optical fiber and a buffer layer at one end face of the ferrule; and (ii) an end stop sized to engage the buffer layer and to contain the optical fiber within said ferrule. In some embodiments the ferrule includes an optical fiber situated within the bore.

Abstract: An optical fiber connector configured to be inserted into an optical fiber adapter according to the present invention is provided. The optical fiber connector includes a housing and an elastic body. The housing has a front end with an opening formed thereon. The elastic body is positioned on the housing and around the opening. When the optical fiber connector is inserted into an axial cavity of the optical fiber adapter, a hollow cylinder of the optical fiber adapter will be inserted into the optical fiber connector through the opening on the front end of the housing and the elastic body on the housing will be in contact with inner walls of the axial cavity of the optical fiber adapter.

Abstract: Disclosed is an optical connector plug that can be securely attached to or detached from a shutter member without damage, regardless of a state of a coupling claw of an optical connector adaptor or existence or non-existence of the coupling claw. In the optical connector plug, a front end of the shutter member can move between a shield position to shield a front end face of a ferrule in an extension state and a non-shield position to expose the front end face of the ferrule to the front side of a housing in a reduction state, when a plug frame and a shutter holding member move between the extension state and the reduction state. In the optical connector plug, in a course in which the shutter holding member is engaged with holding portions protruding in an axial direction of the optical connector adaptor and a grip member moves from the extension state to the reduction state, the front end of the shutter member is spaced to face front ends of the holding portions in the axial direction.

Abstract: An interface converter is provided for mechanically and optically coupling a fiber optic connector with an adapter port. In a preferred embodiment, the interface converter attaches to an SC fiber optic connector and together form a converted fiber optic connector compatible with the adapter port. In certain embodiments, a retractable release sleeve may be removed from the SC fiber optic connector prior to attaching the interface converter. In certain embodiments, the interface converter may be inserted into the adapter port prior to being attached to the SC fiber optic connector.

Abstract: A ferrule assembly comprising: (a) a ferrule body defining a plurality of bores and having an end face having an inner portion and outer portions on opposite sides of said first portion; (b) a plurality fibers disposed in said bores and protruding beyond said end face; and (c) a protruding element on each outer portion, said protruding element having a first or second configuration, in said first configuration, said protruding element comprises a portion of said outer portion that protrudes beyond said inner portion but not as far as said fibers protrude, and in said second configuration, said protruding element comprises at least one fiber in a bore in said outer portion that protrudes beyond any fiber in a bore in said inner portion.

Abstract: An optical connector having a front and back orientation and suitable for operating with a temperature range, the connector comprising: (a) a ferrule comprising a first material having a first coefficient of thermal expansion (COE), and having no greater than a first diameter below a transition temperature with the temperature range, and no less than a second diameter above the transition temperature, the ferrule also comprising an endface, and containing at least one fiber having a fiber end presented at the endface; (b) a spring disposed behind the ferrule and in contact with the ferrule to apply a forward urging force to the ferrule; and (c) a housing comprising a second material having a second COE, the housing defining a bore hole having a diameter greater than the second diameter, and an interface portion having a restricted bore hole having no greater than a third diameter below the transition temperature, and no less than a fourth diameter above the transition temperature; wherein the connector is con

Abstract: An optical fiber connector comprises an outer housing configured to mate with a receptacle and a collar body disposed in the outer housing. The collar body receives and secures a ferrule in a first portion of the collar body. The ferrule includes a central bore that defines an axis. The ferrule further includes a fiber stub disposed in a portion of the central bore, the fiber stub comprising a first optical fiber having a first end proximate to an end face of the ferrule and a prepared second end terminating within the ferrule. The collar body further includes a second portion that includes a housing portion to house a gripping device that grips a second optical fiber.

Abstract: To provide an optical receptacle insulated electrically between the tip section and end section of the optical receptacle so that reduces the possibility of EMI and ESD, the optical receptacle includes a cylindrical sleeve for connecting a plug ferrule; a cylindrical stub ferrule made from an electric insulator, through which an optical fiber is to be inserted, the stub ferrule comprising a front end section inserted into a rear end of the sleeve, and a rear end section formed of a thin section having an outer diameter smaller than that of the front end section; a first holder made of a metal fastened on the stub ferrule at a position located toward the front end section from the thin section; and a second holder made of a metal fastened on the thin section.

Abstract: The disclosure relates to a connector for simultaneously connecting optical fibers and copper conductors, comprising two connector parts (11, 12) which can be fitted together, a first connector part (11) being assigned to a tether cable (13), in which first optical fibers, branched off from a riser cable (14) by means of a furcation adapter, and first copper conductors, likewise branched off from a riser cable (14), are run, a second connector part (12) being assigned to a distribution cable (15), in which second optical fibers and second copper conductors are run, it being possible for the first optical fibers and the second optical fibers as well as the first copper conductors and the second copper conductors to be connected by fitting the two connector parts (11, 12) together, and a hollow-like cutout with a contour that is adapted to the contour of the riser cable (14) being respectively formed both on an underside of a housing of the first connector part (11) and on an underside of a housing of the secon

Abstract: Provided is an optical connector, including a covering member having a holding portion which surrounds the entire circumference of rear end of the housing, a covering portion which covers rear end of a locking lever, and a tool insertion hole which is provided between the holding portion and the covering portion so as to extend through the covering member in an optical axis direction.

Abstract: The invention pertains to an optical ferrule and a method of manufacturing the optical ferrule that can compensate for the fact that the end faces of the fibers contained in the ferrule initially may not be coplanar of each other within required or desired tolerances or otherwise not the exact correct length. Particularly, a cavity is provided within the ferrule to provide room for the fibers to freely bend within at least a range of curvatures within the ferrule so that any difference in the lengths of the fibers can be compensated for by a unique amount of bend in each individual fiber.

Abstract: The invention pertains to an optical coupling method and apparatus in which the connectors are hermaphroditic and each connector comprises a ferrule that provides (1) the coarse alignment of the fibers, (2) the fine alignment of the fibers, and (3) the releasable latching of two such ferrules to each other. Hence, two such ferrules can be used to connect optical fibers without the need for connector housings. The ferrule of this system includes an alignment protrusion and a complementary alignment hole on the front face of the ferrule for providing the fine alignment. Coarse alignment is provided by longitudinally-directed protrusions extending forwardly of the front face, and recesses in the ferrule that are complementary to the protrusion such that two such ferrules can be mated to each other with the protrusions of one such ferrule fitting snugly within the recesses of the other such ferrule.

Abstract: A fiber optic cable is provided with a cable section including at least one length of fiber optic line having a first end and a second end. A first and second plug each have a mechanical body shaped to selectively engage and disengage a jack housing. Each plug has a microlens with a planar surface to engage the fiber optic line end and a convex surface to transceive light in a first collimated beam with a jack optical interface. The fiber optic cable ends are formed in a focal plane of a corresponding plug microlens.

Abstract: An optic connector jack is provided with a punch-down fiber optic cable termination. The jack is made up of a housing with a connector mating interface, for connection to a plug connector, and a cradle for receiving a fiber optic cable. The cradle has at least one U-shaped punch-down blade for securing each fiber optic cable with respect to the housing. A crimping plate overlies the cradle and mates to the housing for securing each fiber optic cable in the cradle. The U-shaped punch-down blade has an open top portion, a closed bottom portion, and an inside diameter about equal to a fiber optic cable diameter. The U-shaped punch-down blade has an interior blade edge, the interior blade edge securing a fiber optic cable by slicing into at least a part of the fiber optic cable circumference. In one aspect, the jack includes a lens for each fiber optic cable.

Abstract: An optical connector includes: an engaging member having a pair of elastic pieces that can be engaged with locking portions on both sides of a receiving-side optical connector; and a movable tubular housing externally fitted to the engaging member, wherein the pair of elastic pieces approaches each other by an engagement with the locking portions on both sides of the receiving-side optical connector, and thereby, the housing becomes movable forward with respect to the portion of the engaging member that engages with the locking portions, and wherein an engagement state between the elastic pieces and the locking portions on both sides of the receiving-side optical connector is maintained as the pair of elastic pieces abuts an inside of the housing thereby regulating a movement in a direction of being separated from each other when the housing has moved forward with respect to the engaging member.

Abstract: An optical fiber connector for terminating an optical fiber is provided. The optical fiber connector includes a housing configured to mate with a receptacle. The connector also includes a collar body disposed in the housing and retained between the housing's outer shell and a backbone. The collar body includes a swivel head coupled to a front end portion of the collar body, where the swivel head is configured to receive a ferrule. The swivel head is configured to pivot with respect to the front end portion of the collar body by a controlled amount upon a side pull force being placed on the connector and/or optical fiber.