Disclosed here are embodiments of an optical fiber ribbon. In the optical fiber ribbon, a plurality of optical fibers are arranged in a row. The optical fibers are embedded in a primary matrix. The primary matrix comprises a base resin and an opacifier pigment. A secondary matrix is disposed around the primary matrix, and a layer of printing is disposed between the primary matrix and the secondary matrix. The secondary matrix has a contrast ratio of from 0.2 to 0.9 as measured according to ASTM D2805. Embodiments of a method of preparing an optical fiber ribbon are also disclosed in which optical fibers are arranged in a row and embedded in a primary matrix. Characteristics of the optical fibers is printed onto the primary matrix, and the primary matrix is coated with a secondary matrix having a contrast ratio of from 0.2 to 0.9 according to ASTM D2805.

The present disclosure provides a cable assembly and a cable indication system. The cable assembly includes a first cable, a second cable, a first connector, a second connector, and a third connector. The first cable includes a jacket defining a first cavity and a second cavity, the first cavity includes a light guide extending through the first cavity, and the second cavity has an open end. The second cable is encased by the first cable in the second cavity, and the second cable extends through the second cavity. The first connector is electrically coupled to a first end of the first cable and includes a first interface for connecting with a first device. The second connector includes a second interface for connecting with the first connector. The third connector includes a third interface for connecting with a second device.

Present disclosure provides a method for grouping of a plurality of optical fibers using first coating layer and magnetic coating layer. The method of the present disclosure includes the step of coating of each of the plurality of optical fibers with a first coating layer and the step of coating of each of the plurality of optical fibers with a magnetic coating layer. Further, the method includes the step of applying magnetic field over the plurality of optical fibers for grouping of the plurality of optical fibers in a predefined manner. Furthermore, the first coating layer serves as a shock absorber to protect the plurality of optical fibers from physical damage.

An optical fiber unit includes an optical fiber ribbon in which a plurality of optical fibers are arranged in parallel, and a colored bundle tape which is longitudinally wrapped or spirally wrapped around an optical fiber ribbon bundle in which the plurality of optical fiber ribbons are stranded together. One end portion in a width direction of the bundle tape and the other end portion in the width direction of the bundle tape overlap each other and are joined to each other, and the bundle tape covers an entire circumference of the optical fiber ribbon bundle.

The method for creating an optical fiber ribbon of the present disclosure includes a first step of arranging a plurality of optical fibers in parallel to each other for creating the optical fiber ribbon. In addition, the method includes a second step of intermittently bonding the plurality of optical fibers partially at specific intervals using a matrix material. Further, intermittent bonding of the plurality of optical fibers is in pattern of text. Furthermore, intermittent bonding of the plurality of optical fibers allows the optical fiber ribbon to bend along preferential axis. Moreover, intermittent bonding of the plurality of optical fibers is in pattern of text.

A connector is employed for bonding a locatable tracer wire with a lead wire. A base has a first receiving slot and an axial slot which intersects the receiving slot. A contact plate is slidably receivable in the axial slot and is dimensioned to accommodate a tracer wire and an insulator cover received in the receiving slot at a first axial position and to sever the cover and conductively engage the tracer at a second axial position. A fastener threadably engages the base. Upon tightening the fastener to the base, a shoulder extending from the contact plate is displaced and ultimately stopped so that the plate is disposed at the second position. The lead wire is also secured by the fastener.

A method of connecting lengths of multicore optical fibers (MCFs) to one another. First and second lengths of a MCF whose cores are arranged in a certain pattern about the fiber axis to define pairs of cores are provided, and the cores of each pair of cores are disposed symmetrically with respect to a key plane that includes the axis of the fiber. Ends of the first and the second lengths of the MCF are arranged in axial alignment with one another, and the key plane at the end of the first length of the MCF is aligned with the key plane at the end of the second length of the MCF. Each defined pair of cores in the first length of the MCF is thereby positioned to mate with the same defined pair of cores in the second length of the MCF.

An optical fiber colored core wire includes: a bare optical fiber; a primary layer that comprises a UV curable resin that covers the bare optical fiber; a secondary layer that comprises a UV curable resin that covers the primary layer; and a colored layer disposed outside the secondary layer and that comprises a colored UV curable resin. The primary layer has a Young's modulus that is greater than or equal to 70% of a saturated Young's modulus of the primary layer.

An electronically-managed optical fiber connection system is provided. A smart ferrule carrier comprises a plurality of ferrule bays configured to accept a tagged optical ferrule assembly. Each tagged optical ferrule assembly comprises an identification (ID) tag storing identification information for the optical ferrule assembly. A smart carrier board comprising a carrier controller is configured to read and/or write information to/from the ID tag of each tagged optical ferrule assembly. A smart carrier adapter is configured to accept a plurality of smart ferrule carriers, the smart carrier adapter including an adapter controller system. The adapter controller system includes an adapter controller configured to communicate with the carrier controller of each installed smart ferrule carrier and a system controller.

A reversible fiber optic cassette for mounting with other like cassettes in a rack comprising a cassette receiving tray, the tray comprising a plurality of cassette engaging features on an upper surface is disclosed. The cassette comprises N duplex pairs of optic fiber receptacles arranged along a front thereof, a multifiber receptacle on a back thereof and 2*N optic fiber segments each between a respective one of the optic fiber receptacles and the multifiber receptacle, N discrete port identifiers on a first surface thereof and N discrete port identifiers on a second surface opposite the first surface. The first set of N identifiers is the same as the second set of N identifiers and for M between 1 to N, an M.sup.th port identifier of the first set and an (N-M+1).sup.th port identifier of the second set is adjacent an M.sup.th one of the duplex pairs of optic fiber receptacles.