A flexible flat cable includes a highly reflective member having a plate shape, light-transmitting signal transmission members spaced apart from each other on a first surface of the highly reflective member, conductive signal transmission members spaced apart from each other on the first surface of the highly reflective member, a highly reflective adhesive member that fixes the light-transmitting signal transmission members and the conductive signal transmission members to the highly reflective member, and couples the highly reflective member to a non-conductive member, the non-conductive member including a first surface in contact with the highly reflective adhesive member, and a second surface opposite to the first surface of the non-conductive member, an adhesive member that is disposed on the second surface of the non-conductive member, and couples an electrical shield member to the non-conductive member, and the electrical shield member coupled to the non-conductive member by the adhesive member.

In order to provide a cable for a system for conducting and distributing electrical energy and for providing a fast data-conducting communication link, with which high data transmission rates can also be realized in a future-proof manner, and which can be easily used in a system for conducting and distributing electrical energy and for providing a fast data-conducting communication link, a cable is proposed for a system for conducting and distributing electrical energy and for providing a fast data-conducting communication link, comprising a sheathing, wherein at least one electrical line and an optical conductor are embedded in the sheathing, and wherein the cable has a cross-section with a one-fold rotational symmetry.

The present disclosure relates to a fiber optic network configuration having an optical network terminal located at a subscriber location. The fiber optic network configuration also includes a drop terminal located outside the subscriber location and a wireless transceiver located outside the subscriber location. The fiber optic network further includes a cabling arrangement including a first signal line that extends from the drop terminal to the optical network terminal, a second signal line that extends from the optical network terminal to the wireless transceiver, and a power line that extends from the optical network terminal to the wireless transceiver.

Provided is a medical observation system capable of preventing disconnection of metal cables without increasing the thickness of a braided shield wire. The medical observation system includes a transmission cable including: an optical cable having one or more optical fiber cores; a plurality of metal cables arranged around the optical cable; and a tension member made of a high-strength fiber, and disposed in parallel with an extending direction of the optical cable.

An optically traceable patch cord includes a cable extending from a first connector at a first end to a second connector at a second end. A trace assembly in the cable is located between the first end of the cable and the second end of the cable. An optical tracing fiber extends from the trace assembly to one of the first connector and the second connector.

Embodiments of the disclosure relate to a method of preparing a bundled cable. In the method, a plurality of subunits is wound around a central member in one or more layers of subunits to form the bundled cable. For a section of the central member, each layer of subunits has a pitch over which a subunit of the layer of subunits makes one revolution around the section of the central member and a length of the subunit required to make the one revolution. The subunits are configured to have a nominal helical length equal to the ratio of a nominal length to a nominal pitch. Further, in the method, a measurement of the bundled cable is monitored, and a winding rate of the plurality of subunits is adjusted based on the measurement in order to account for deviations from the nominal helical length.

A power and optical fiber interface system includes a housing having an interior. A cable inlet is configured to receive a hybrid cable having an electrical conductor and an optical fiber. An insulation displacement connector (IDC) is situated in the interior of the housing configured to electrically terminate the conductor, and a cable outlet is configured to receive an output cable that is connectable to the IDC and configured to output signals received via the optical fiber.

A power cable joint includes splices and extra-length portions of first and second optical fibers which are included in respective first power cable and second power cable, and a cable joint sleeve (100). The abovementioned splices and extra-length portions are accommodated in an organizer (10) that includes a tray (20) having a recessed area (22) and configured to shapingly fit to an outer surface (101) of the cable joint sleeve (100). In particular, splices and extra-length portions of optical fibers are housed in an upper surface (21) of the tray (20). The organizer (10) further includes a fastener (40) configured to secure the tray (20) to the outer surface (101) of the cable joint sleeve (100) and a cover (50) configured to at least partially cover the upper surface (21) of the tray (20).

A cable includes a transmissive core; a jacket surrounding the transmissive core, which has at least an outermost polymeric layer; and an external semi-conductive layer around and in direct contact with the outermost polymeric layer of the jacket. The external semi-conductive layer is made of a composition comprising a base polymer material and an electrically conductive filler. The electrically conductive filler includes carbon nanotubes.

An optical fiber trunk cable breakout canister comprising a main canister portion having a first smaller end and a second larger end. A stop is defined at a predetermined axial distance from the second larger end. A nozzle plate is received in the second larger end of the main canister portion and engages the stop, the nozzle plate carrying a plurality of axial nozzles. The distance between the nozzle plate and the second larger end of the main canister portion is greater than the axial length of the nozzles. In this embodiment, potting material is located in the main canister portion so as to cover and seal ends of the nozzles.