A traceable cable and method of forming the same. The cable includes at least one data transmission element, a jacket, and a side-emitting optical fiber. The side-emitting optical fiber includes a core having a first index of refraction and a cladding having a second index of refraction that is different than the first index of refraction. The cladding substantially surrounding the core and has an exterior surface with spaced apart scattering sites penetrating the exterior surface. The scattering sites are capable of scattering light so that the scattered light is emitted from the side-emitting optical fiber at discrete locations. The core also includes one or more mode coupling features capable of changing at least some low order mode light in the side-emitting optical fiber to high order mode light, thereby increasing light emitted from the scattering sites.

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 a plurality of optic fiber receptacles arranged along a front thereof, a multifiber receptacle on a back thereof and a plurality of optic fiber segments each between a respective one of the optic fiber receptacles and the multifiber receptacle, a first tray engaging feature extending from the first surface and configured for engaging with one of the cassette engaging features, a second tray engaging feature extending from the second surface and configured for engaging with one of the cassette engaging features; and a release mechanism comprising an actuator for selectively disengaging the tray engaging feature from the engaged one of the cassette engaging features.

An object recognition apparatus and method are disclosed. The object recognition apparatus includes an illuminable cable (C2), disposed on a target recognized object (C1) and used for highlighting the target recognized object (C1) to a striking state when a light source is guided into the illuminable cable (C2). By adopting a recognition method for the object recognition apparatus, the accuracy and recognition efficiency of recognition of physical connection in an optical fiber network system are improved.

A traceable cable assembly includes a traceable cable having at least one data transmission element, a jacket at least partially surrounding the data transmission element, and first and second tracing optical fibers extending along at least a portion of a length of the traceable cable. The traceable cable assembly also includes a connector provided at each end of the traceable cable. The first and second tracing optical fibers each have a light launch end and a light emission end. The light launch ends of the first and second tracing optical fibers each include a bend. The bend allows for launching of light into the light launch ends without disengaging the first or second connectors from corresponding connector receptacles.

The present application described methods an apparatus for locating and/or monitoring subsea cables (101) having an optical fibre (105) deployed along its length. The optical fibre (105) is connected to a distributed acoustic sensing (DAS) interrogator unit to interrogate the optical fibre to provide a fibre optic DAS sensor. To locate the cable an acoustic stimulus is transmitted into the water from one or more known locations. The time of arrival of an acoustic signal matching the stimulus at the sensing portions of the DAS fibre can be detected and used to determine information about the location of those sensing portions to the known location. The DAS signals returns can also be monitored under ambient conditions to detect any signals indicative of likely damage to the cable.

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.

A method for use in connection with installing a cable into a conduit having a first conduit end and a second conduit end, comprising the steps of —providing the cable with a metallic attribute, —providing within or proximate to the conduit, sensing means for sensing the metallic attribute, —introducing the cable into the first conduit end and driving it towards the second conduit end and —detecting that the sensing means has sensed the metallic attribute by sensing a change in inductance levels of the sensing means.

An optical fiber having a coating that includes a photoreactive marking compound is described. The photoreactive marking compound has two states that differ in the intensity and/or wavelength of fluorescence. Exposure of the photoreactive marking compound to electromagnetic radiation induces a transformation of the photoreactive marking compound from one state to the other state. The difference in fluorescence between the two states provides a detectable contrast that can be used to mark the optical fiber. A pattern of marks can be customized to different optical fibers to provide unambiguous identification of individual fibers. The coating may also include a pigment, where either or both of the pigment and photoreactive marking compound may function as a marker for identifying the optical fiber. The method extends generally to marking of films, coatings, and articles made of polymers or plastics.

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.

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.