Systems and methods for physical cable route tracing are provided. In one embodiment, a cable comprises: one or more of either electrical conductors or optical fibers; a cable sheath around the one or more of either electrical conductors or optical fibers; and a pattern of cable tracing facilitation markings located on an exterior of the cable sheath; wherein the cable tracing facilitation markings comprise either: a visually varying pattern that gradually changes along a length of the cable sheath; or a series of coded markings of an ordered sequence pattern.

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.

An apparatus including a first light pipe, a second light pipe and a tracing fiber. The first light pipe may comprise slot features and may be configured to receive light. The second light pipe may comprise the slot features and may be configured to emit the light. The tracing fiber may be configured to propagate the light from the first light pipe to the second light pipe. The first light pipe may focus the light by refraction into the tracing fiber. The slot features of the second light pipe may be configured to scatter the light to provide omnidirectional emission of the light. The tracing fiber may be bundled with one or more data carrying lines in a cable. Each of the data carrying lines may be configured to enable a communication of data. The tracing fiber may be configured to propagate the light without interrupting the communication of data.

To provide a connector plug that makes it possible to facilitate a plurality of persons' confirmation of a connector plug before its removal or after its insertion and to prevent erroneous work. The connector plug according to the present invention has a discoloration member mounted on a gripping portion for pinching during work. The color of the discoloration member changes due to heat of a worker's fingertips when the worker pinches the connector plug or pressure when the worker pinches the connector plug. The discoloration member is discolored by one worker pinching the connector plug. Another worker looks at the discolored discoloration member, and then is able to confirm whether the connector plug is a work target.

An optical fiber cable includes a cable jacket defining a cable core, and a plurality of fiber bundles extending longitudinally through the core. Each fiber bundle comprises a plurality of optical fibers and a combination of color schemes, one color scheme that uniquely identifies each individual fiber by a particular base color, and a second color scheme that uniquely identifies each individual bundle based on a common color of one element in the bundle.

Disclosed is a patch cord identification inspection system. The patch cord identification inspection system includes a patch cord having first and second connectors which are coupled to both end parts of an optical fiber cable and are detachably connected to predetermined electronic devices and in which first and second light-emitting diode (LED) modules are respectively embedded, and an identification inspector selectively slidably and detachably coupled to any one of the first and second connectors and configured to identify and inspect electrical connection states of the first and second connectors on the basis of lighting states of the first and second LED modules.

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.

The present disclosure provides a rollable optical fiber ribbon. The rollable optical fiber ribbon includes a plurality of optical fibers positioned along a longitudinal axis of the rollable optical fiber ribbon. In addition, the rollable optical fiber ribbon includes a matrix material covering the plurality of optical fibers to provide flexibility to the rollable optical fiber ribbon. Further, the rollable optical fiber ribbon includes at least one colour line marking on the rollable optical fiber ribbon along the longitudinal axis of the rollable optical fiber ribbon.

A non-metallic layer stranded optical cable with a reversal point capable of being positioned and a detection method thereof, which solves the problems of determining a reversal point of a cable core and performing an operation of drawing out an optical fiber from the optical cable. The present invention relates to a non-metallic layer stranded optical cable, and the key points of the technical solution thereof includes a cable core and a metal film provided at each reversal point of the cable core, and an outer sheath is provided on the cable core.

The present disclosure provides an intermittently bonded optical fibre ribbon. The intermittently bonded optical fibre ribbon includes a plurality of optical fibres such that adjacent optical fibre of the plurality of optical fibres is bonded intermittently along the length by a plurality of bonds. The plurality of bonds is defined by a plurality of colours. The plurality of bonds may form a predefined pattern. The predefined pattern may be used for identification of the intermittently bonded optical fibre ribbon.