Abstract: The present disclosure describes fusion spliced cable assemblies.

Abstract: The present disclosure describes active optical cable assemblies. A cable assembly includes a fixed active optical connector having a transceiver, a ruggedized optical fiber cable integrated with the fixed active optical connector, a main cable assembly comprising one or more optical fiber cables, wherein the ruggedized cable is spliced to the main cable assembly; and a removable shroud configured to surround at least a portion of the fixed active optical connector plugged into a remote radio unit and to be secured to a remote radio unit. Active optical cable and remote radio unit systems and kits are also described.

Abstract: The present disclosure describes fusion spliced cable assemblies.

Abstract: The present disclosure describes active optical cable assemblies. A cable assembly includes a fixed active optical connector having a transceiver, a ruggedized optical fiber cable integrated with the fixed active optical connector, a main cable assembly comprising one or more optical fiber cables, wherein the ruggedized cable is spliced to the main cable assembly; and a removable shroud configured to surround at least a portion of the fixed active optical connector plugged into a remote radio unit and to be secured to a remote radio unit. Active optical cable and remote radio unit systems are also described.

Abstract: A fiber optic cable breakout assembly includes: a fiber optic cable including a plurality of first optical fibers and a first jacket surrounding the optical fibers; a breakout canister; a plurality of pigtail cords, each of the pigtail cords including a second optical fiber partially encased in a second jacket and an optical connector, each of the pigtail cords extending away from the canister, each of the optical fibers extending through the canister; and a flexible furcation tube attached to and extending between the fiber optic cable and the breakout canister, the furcation tube including an armored inner layer and a polymeric outer layer, wherein each of the first optical fibers is spliced to a respective second optical fiber within the inner layer of the furcation tube.

Abstract: The present disclosure describes sealing boots for protecting an optical interconnection. A sealing boot may include a main body having an interior cavity, the interior cavity having an annular recess adjacent to one end of the main body, the annular recess configured to receive a feature of a remote radio unit, and a neck merging with the opposing end of the main body and having a cylindrical inner surface that defines a bore that is continuous with the cavity of the main body, the inner surface having an inner diameter that is less than an inner diameter of the interior cavity of the main body. The sealing boot is configured to surround at least a portion of a fixed active optical connector when the fixed active optical connector is plugged into the remote radio unit.

Abstract: The present disclosure describes fusion spliced cable assemblies.

Abstract: A hybrid jumper cable assembly includes: a plurality of power conductors; a plurality of optical fibers; a jacket surrounding the power conductors and the optical fibers; one or more connectors connected with the power conductors and the optical fibers; and a fuse electrically connected with one of the plurality of power conductors.

Abstract: The present disclosure describes sealing boots for protecting an optical interconnection. A sealing boot may include a main body having an interior cavity, the interior cavity having an annular recess adjacent to one end of the main body, the annular recess configured to receive a feature of a remote radio unit, and a neck merging with the opposing end of the main body and having a cylindrical inner surface that defines a bore that is continuous with the cavity of the main body, the inner surface having an inner diameter that is less than an inner diameter of the interior cavity of the main body. The sealing boot is configured to surround at least a portion of a fixed active optical connector when the fixed active optical connector is plugged into the remote radio unit.

Abstract: The present disclosure describes active optical cable assemblies. A cable assembly includes a fixed active optical connector having a transceiver, a ruggedized optical fiber cable integrated with the fixed active optical connector, a main cable assembly comprising one or more optical fiber cables, wherein the ruggedized cable is spliced to the main cable assembly; and a removable shroud configured to surround at least a portion of the fixed active optical connector plugged into a remote radio unit and to be secured to a remote radio unit. Active optical cable and remote radio unit systems are also described.

Abstract: A fiber optic cable breakout assembly includes: a fiber optic cable including a plurality of first optical fibers and a first jacket surrounding the optical fibers; a breakout canister; a plurality of pigtail cords, each of the pigtail cords including a second optical fiber partially encased in a second jacket and an optical connector, each of the pigtail cords extending away from the canister, each of the optical fibers extending through the canister; and a flexible furcation tube attached to and extending between the fiber optic cable and the breakout canister, the furcation tube including an armored inner layer and a polymeric outer layer, wherein each of the first optical fibers is spliced to a respective second optical fiber within the inner layer of the furcation tube.

Abstract: A hybrid jumper cable includes: a pair of power conductors; a pair of optical fibers; a jacket surrounding the pair of power conductors and the pair of optical fibers; a hybrid connector connected with the pair of power conductors and the pair of optical fibers; a capacitor electrically connected to each of the pair of power conductors; and a conduit attached to the hybrid connector, the capacitor residing in the conduit.

Abstract: A cable-connector assembly includes: a cable including signal-carrying members, the signal-carrying members being circumferentially surrounded by a conduit; a connector configured to mate with a mating connector, the signal carrying members being connected with ports on the connector; and a generally cylindrical housing that circumferentially surrounds the signal-carrying members, the housing including a narrow neck that fits within an end of the conduit and a wide main portion that engages the connector.

Abstract: The present disclosure describes fusion spliced cable assemblies.

Abstract: A cable-connector assembly includes: a cable including signal-carrying members, the signal-carrying members being circumferentially surrounded by a conduit; a connector configured to mate with a mating connector, the signal carrying members being connected with ports on the connector; and a generally cylindrical housing that circumferentially surrounds the signal-carrying members, the housing including a narrow neck that fits within an end of the conduit and a wide main portion that engages the connector.

Abstract: An OVP module that connects with a hybrid trunk cable includes: a mounting frame; an overvoltage unit mounted in the mounting frame and configured to create an open electrical circuit when experiencing a voltage higher than a predetermined threshold; a first contact configured to receive a first set of power conductors from a hybrid trunk cable; a second contact configured to receive a second set of power conductors from the hybrid trunk cable; a first OVP conductor connected between the first contact and the overvoltage unit; a second OVP conductor connected between the second contact and the overvoltage unit; a third contact configured to receive a first set of power cords; a fourth contact configured to receive a second set of power cords; a third OVP conductor connected between the overvoltage unit and the third contact; and a fourth OVP conductor connected between the overvoltage unit and the fourth contact.

Abstract: A coaxial connector, the coaxial connector interconnectable with a coaxial cable by a process including providing a connector body with a bore; inserting a leading end of the coaxial cable into the bore from a cable end of the connector body, and laser welding between the outer conductor and the connector body from a connector end of the connector body.

Abstract: A transition assembly for interconnecting a hybrid trunk cable and electronic equipment includes: an enclosure having first and second ends, first and second side walls, and a cavity; a hybrid trunk cable comprising first and second sets of pluralities of power conductors and a plurality of optical fibers, wherein the first and second sets of power conductors enter the enclosure at the first end; first and second sets of pluralities of connectors mounted to at least one of the first and second side walls; and an overvoltage protection module (OVP module).

Abstract: A connector assembly with overvoltage protection includes: a housing having a cavity therein; a printed circuit board residing in the cavity of the housing; an overvoltage unit mounted on the printed circuit board and configured to create an open electrical circuit when experiencing a voltage higher than a predetermined threshold; a plurality of first electrical contacts adjacent a first edge of the printed circuit board and electrically connected to the overvoltage unit, each of the plurality of first electrical contacts configured to receive a respective one of a plurality of electrical conductors of a hybrid jumper cable; a plurality of second electrical contacts adjacent a second edge of the printed circuit board and electrically connected to the overvoltage unit, each of the plurality of second electrical contacts configured to receive a respective one of a plurality of electrical conductors of a piece of communications equipment; and a plurality of optical connectors mounted within the cavity configured