Abstract: Trunk gland adapters include an adapter body having an internal bore that is sized to receive a trunk cable gland so that a front end of the trunk cable gland extends through a front opening of the internal bore and a plurality of attachment clips that are configured to releasably attach the adapter body to a mounting aperture in a wall of a fiber optic enclosure. Related trunk gland units and methods of routing a trunk cable into an enclosure are also disclosed.

Abstract: A method and system connects multiple cores within one fiber, e.g., a multi-core fiber (MCF), to multiple fibers with single-cores. The single-core fibers can then be terminated by traditional envelopes, such as a single core LC envelope. A connector holds the single-core fibers into a pattern that matches a pattern of all, or a sub group, of the individual cores of the MCF. The single-core fibers may all be terminated to individual connectors to form a fanout or breakout cable. Alternatively, the single-core fibers may extend to another connector wherein the single-core fibers are regrouped into a pattern to mate with the cores of another MCF, hence forming a jumper. One or more of the single core fibers may be terminated along the length of the jumper to form a jumper with one or more tap accesses.

Abstract: The invention addresses the coupling of light between one or more multicore fibers and optoelectronic transducers, such as lasers or photodetectors, and/or single core fibers. More specifically, the invention utilizes a single microlens element to couple multiple optical data signals between multiple optoelectronic transducers and multiple cores of a multiple-core fiber (MCF), or to couple signals from multiple single-core fibers to multiple cores of a MCF. At least one optoelectronic transducer and at least one fiber core are substantially removed from the microlens axis and the MCF axis, possibly by different amounts, and cores of the MCF may optionally be polished to be non-telecentric to the axis of the microlens element.

Abstract: A cable includes a jacket surrounding first and second insulated conductors and a first dielectric tape, wherein the first insulated conductor is twisted with the second insulated conductor with the first dielectric tape residing therebetween to form a first twisted pair. The cable's jacket may also surround additional twisted pairs, which are similarly formed. In alternative or supplemental embodiments of the invention, the first dielectric tape has a hollow core possessing a gas or material with a lower dielectric constant and/or at least a first side of said first dielectric tape facing to said first insulated conductor includes a plurality of ridges and valleys.

Abstract: A multi-cable breakout assembly includes: a plurality of cables arranged in a rectangular array of M rows×N columns, wherein M and N are positive whole numbers greater than one; a first sleeve that encircles the plurality of cables; first and second ribbon members, the first ribbon member being threaded through the plurality of cables to separate the cables into M rows; and the second ribbon member being threaded through the plurality of cables to separate the cables into N columns; and a second sleeve that overlies an end of the first sleeve and the first and second ribbon members.

Abstract: Communications connectors include a housing and a plurality of substantially rigid conductive pins that are mounted in the housing. The conductive pins are arranged as a plurality of differential pairs of conductive pins that each include a tip conductive pin and a ring conductive pin. Each conductive pin has a first end that is configured to be received within a respective socket of a mating connector and a second end. The tip conductive pin of each differential pair of conductive pins crosses over its associated ring conductive pin to form a plurality of tip-ring crossover locations.

Abstract: A cable includes a spacer surrounding a cable core. The cable core includes four twisted pairs. A separator is disposed amongst the twisted pairs. The separator may be formed with three layers, wherein a middle layer is conductive and outer layers are nonconductive. A jacket surrounds the spacer, and a shielding layer may reside between the jacket and the spacer. The spacer may be formed of plural fibers or a polymer. Preferably, the spacer presents a lower dielectric constant per unit volume than the jacket. The separator may have a tape shape or a plus shape.

Abstract: Printed circuit boards for communications connectors are provided that include a dielectric substrate formed of a first insulative material having a first dielectric constant. First and second pairs of input terminals and first and second pairs of output terminals are provided on the dielectric substrate. A first differential transmission line electrically connect the first pair of input terminals to the first pair of output terminals, and a second differential transmission line electrically connect the second pair of input terminals to the second pair of output terminals. The dielectric substrate includes an opening that is positioned between the conductive paths of the first differential transmission line, the opening containing a second insulative material having a second dielectric constant.

Abstract: Communications jacks include at least first through third jackwire contacts and a flexible substrate that has a first finger and a second finger. The first jackwire contact and the third jackwire contact are each mounted on the first finger and the second jackwire contact is mounted on the second finger.

Abstract: Reduced-pair Ethernet patch cords include a twisted pair cable that has a pair of insulated conductors that are contained within a cable jacket. A connector is mounted on a first end of the cable. The connector includes a connector housing and a strain relief unit that is mounted on the cable at the interface between the cable and the connector housing. The strain relief unit includes a plurality of internal protrusions that contact the cable jacket.

Abstract: A fiber optic trunk cable that can be used for connecting multi-channel transceivers includes: a plurality of optical fibers; and first and second terminals attached to opposite ends of the fibers, each of the terminals having an alignment key. The fibers enter the first terminal in an arrangement of 2N rows, wherein N is an integer, and enter the second terminal in an arrangement of 2N rows. Each fiber defines a position in the first terminal that is row-inverted to the position the fiber defines in the second terminal. Such a cable can be employed with appropriate equipment cords and transceivers.

Abstract: A sliding tray is configured to support one or more optical communications modules and includes a body portion having one or more mounting locations for the one or more optical communications modules, a trough projecting from the body portion and configured to support optical fibers connected to the one or more optical communications modules, and a cover pivotably connected to the tray for selectively covering the trough.

Abstract: Patch cords are provided that include a communications cable that has at least first through fourth conductors and a plug that is attached to the cable. The plug includes a housing that receives the cable, a printed circuit board, first through fourth plug contacts, and first through fourth conductive paths that connect the first through fourth conductors to the respective first through fourth plug contacts. The first and second conductors, conductive paths, and plug contacts form a first differential transmission line, and the third and fourth conductors, conductive paths, and plug contacts form a second differential transmission line. Each of the first through fourth plug contacts has a first segment that extends longitudinally along a first surface of the printed circuit board, and the signal current injection point into the first segment of at least some of the first through fourth plug contacts is into middle portions of their respective first segments.

Abstract: Methods of executing patching connection changes in a patching field are provided in which an electronic work order is received on a display located at the patching field, the electronic work order specifying the patching connection change. A technician may perform the patching connection change. Then, an electronic message may be sent from the patching field indicating that the patching change has been completed.

Abstract: Communications jacks include a housing having a plug aperture that is configured to receive a mating RJ-45 plug along a longitudinal axis and eight jackwire contacts that are arranged as four differential pairs of jackwire contacts, each of the jackwire contacts including a plug contact region that extends into the plug aperture. A first of the jackwire contacts is configured to engage a longitudinally extending surface of a first blade of a mating RJ-45 plug when the mating RJ-45 plug is fully received within the plug aperture.

Abstract: A communications connector includes a printed circuit board having a first internal conductive layer and first and second external conductive layers that are stacked with dielectric layers therebetween. The printed circuit board has input terminals, output terminals and signal current carrying conductive paths which electrically connect respective ones of the input and output terminals. The signal current carrying conductive paths are arranged in pairs to form differential transmission lines. The first signal current carrying conductive path includes a first segment that is on the first internal conductive layer which is routed in a vertically stacked arrangement with a second segment of the second signal current carrying conductive path, the first and second signal current carrying conductive paths being part of the same differential transmission line.

Abstract: Patch cords include a communications cable that has a first conductor and a second conductor that form a first differential pair, and a third conductor and a fourth conductor that form a second differential pair and a plug that is attached to the communications cable. The plug includes a housing that receives the communications cable, first through fourth plug contacts that are within the housing, and a printed circuit board. The printed circuit board includes first through fourth conductive paths that connect the respective first through fourth conductors to respective ones of the first through fourth plug contacts. The plug further includes a first conductive shield that extends above a top surface of the printed circuit board that is disposed between the first differential pair and the second differential pair.

Abstract: Communications jacks include a housing having a plug aperture. A plurality of spring members extend into the plug aperture, and a plurality of plug contacts are mounted on respective ones of the spring members. The communications jack further includes a plurality of fixed contacts. Each fixed contact is configured to be in electrical contact with a respective one of the plug contacts when a plug is received within the plug aperture.

Abstract: A communications cable payout bag includes: a main compartment configured to hold a communications cable package; a shoulder strap attached to the exterior of the bag; a pair of handle straps attached to the exterior of the bag, wherein each handle strap is shorter than the shoulder strap; a cable payout passageway between the main compartment and the exterior of the bag; and a closure mechanism configured to close the main compartment.

Abstract: A fiber optic adapter includes a mounting block having a first opening and a through opening extending into the mounting block from the first opening with a seat for receiving a body portion of a fiber optic connector and at least one flexible projection with a first end defining an aperture that is smaller than the first opening. The at least one flexible projection is configured to flex away from a rest position and away from a longitudinal axis of the through opening to allow the body portion of the fiber optic connector to reach the seat and configured to return toward the rest position when the fiber optic connector reaches the seat and to substantially prevent the removal of the fiber optic connector in a direction opposite its insertion direction when the at least one flexible projection is in the rest position.