Abstract: A communications cable is disclosed. The cable includes a first circuit configured to receive electrical data signals from a data source via an input connector, and convert the electrical data signals into optical signals for transmission by way of one or more optical fibers. The cable includes a second circuit configured to convert the optical signals received via the one or more optical fibers back to electrical data signals for providing to a data sink via an output connector. The cable includes a third circuit for applying pre- and post-signal conditioning to bi-directional control data for transmission to and received from the data sink via wires. The cable includes a fourth circuit for applying pre- and post-signal conditioning to bi-directional control data for transmission to and received from the data source via wires. The pre- and post-signal conditioning compensate for capacitance and/or resistance effects on the signals introduced by the wires.

Abstract: An embodiment of a wellbore cable comprises a cable core, at least a first armor wire layer comprising a plurality of strength members and surrounding the cable core, and at least a second armor wire layer comprising a plurality of strength members surrounding the first armor wire layer, the second armor wire layer covering a predetermined percentage of the circumference of the first armor wire layer to prevent torque imbalance in the cable.

Abstract: An optical fiber cable including an optical fiber ribbon in a pipe, wherein the ribbon includes at least two optical fibers arranged side by side, and wherein at least two of the optical fibers are bonded intermittently along a length of the fibers.

Abstract: An embodiment of the invention enables each core in an end face to be readily identified by observation of either one end face, regardless of the presence or absence of a twist of a pertinent MCF and difference of ends. In a cross section of the MCF, a core group constellation has symmetry but each core in a core group is identifiable by breaking of all types of symmetry in a common cladding, defined by a combination of the core group constellation with the common cladding, or, by making the fiber ends distinguishable.

Abstract: A transition device for interconnecting a hybrid trunk cable and electronic equipment includes: an enclosure having first and second ends; a trunk power connector mounted to the first end of the enclosure; a trunk optical connector mounted to the first end of the enclosure; and a plurality of hybrid jumper cables exiting the second end of the enclosure, each of the hybrid jumper cables including at least two power conductors terminated with jumper power connectors and at least one optical fiber terminated with a jumper optical connector.

Abstract: A remote radio head is provided. The remote radio head includes at least one integrated connection terminal for integrating and receiving at least one optical signal with at least one power source, a power supply unit which receives and supplies the power source by converting into an internal driving power source of a corresponding remote radio head, a photoelectric/electrooptic conversion unit for receiving and converting the optical signal into an electric signal, a framer for restoring the electric signal converted in the photoelectric/electrooptic conversion unit according to a preset signal demodulation format, a digital signal processing unit receives a signal outputted from the framer to adjust a waveform and a level in a digital level and a transmission and reception signal conversion module which converts a signal into a high-frequency transmission wireless signal, and amplifies the signal at a high power to output the signal to an antenna side.

Abstract: A hybrid service terminal for use in a passive fiber optic network comprises a plurality of optical fiber connectors, each coupled to a respective optical fiber for receiving downstream optical frames from an Optical Line Terminal (OLT); a plurality of hybrid fiber/copper connectors, each of the hybrid fiber/copper connectors coupled to a respective one of the plurality of optical fiber connectors; and a plurality of electrical connectors configured to receive electrical signals from a multi-line converter module over a respective one of a plurality of electrical conductors. One of the plurality of hybrid fiber/copper connectors is configured to provide the downstream optical frames to the multi-line converter module for conversion to the electrical signals.

Abstract: New optical ground wire (OPGW) cable structures are proposed. These OPGW cables are designed to reduce or minimize the net magnetic field B?NET parallel to the direction {circumflex over (z)} of light propagation resulting from a lightning strike on the cable. A reduction in the net magnetic field B?NET parallel to the direction {circumflex over (z)} of light propagation yields a reduction in the amount and speed of state of polarization (SOP) rotation resulting from a lightning strike on the cable due to the Faraday effect. OPGW cables constructed according to these new OPGW cable structures fulfill their dual function to shield the high-voltage conductors from lightning strikes and to support coherent optical communications.

Abstract: A cable assembly with electrical conductors and fiber optic lines includes a hybrid cable, electrical tethers, a fiber optic tether, and a joining location thereof that includes a shielding unit establishing an electrical contact between shielding of the hybrid cable and shielding of the respective electrical tether cables. The shielding unit includes a central body of an conductive material surrounding the hybrid and tether cables at the joining location, where the central body is in electrical contact with the shielding of the hybrid cable and with the shielding of each electrical tether.

Abstract: A shielded combined optical communication and conductor cable is provided. The cable includes a cable body having an inner surface defining a channel within the cable body. The cable includes an optical transmission element located within the channel and an electrical conducting element located within the channel. The cable includes an electromagnetic shield located within the channel and surrounding at least the electrical conducting element. The electromagnetic shield includes an elongate yarn strand or other strand material that supports a metal material that acts to limit electromagnetic fields from traversing across the electromagnetic shield. The strands may be unbraided and may be helically wrapped or longitudinally positioned within the cable body.

Abstract: A plug connector for connecting optical fibers to an electrical receptacle connector includes a housing defining a cavity therein. At least one printed circuit board (PCB) is disposed in the housing cavity. The PCB includes one or more optoelectronic components disposed on its top surface and electrical contacts disposed proximate a mating edge of the PCB for mating with the receptacle connector. The electrical contacts are electrically connected to the one or more optoelectronic components. One or more optical fibers enter the housing cavity through a housing opening and are optically coupled to the optoelectronic components. A structure comprising a top surface is disposed within the housing cavity between the housing opening and the PCB. The plurality of the optical fibers extends over the top surface of the structure and over at least a portion of the top surface of the PCB.

Abstract: A plurality of telecommunications connections are installed in a distribution network by connecting a series of distribution points using a multicore cable comprising a plurality of cores having a common enclosure, some of the cores carrying fiber tubes into which optical fiber may later be introduced, and other cores carrying an electrical power supply. One or more cores may be diverted from a longer cable run to serve a local distribution point by rupturing a web connecting the core to the rest of the cable, thus allowing the remaining cores to be uninterrupted at the point of divergence. An alternative embodiment intended for underground use provides for apertures to be opened in a protective sheath to expose the individual cores required to be diverted to a local distribution point.

Abstract: Provided is an optical fiber ribbon capable of concurrently ensuring mid-span access performance and cable production performance. The optical fiber ribbon 1 includes three or more optical fibers 2 arranged in parallel and connecting portions 3 connecting the adjacent optical fibers 2, the connecting portions 3 being formed intermittently in each of a ribbon longitudinal direction X and a ribbon width direction Y. The optical fiber ribbon 1 including the connecting portions 3 having split strength which is set in the range from 1.50 gf to 21.0 gf, contributes to exhibiting both the mid-span access performance and the cable production performance.

Abstract: A fiber optic cable includes an optical fiber, a strength layer assembly disposed adjacent to the optical fiber and an outer jacket surrounding the strength layer assembly. The strength layer assembly includes a strength layer, an outer layer and an inner layer. The strength layer includes a binder and a plurality of reinforcing fibers embedded within the binder. The strength layer has a first surface and an oppositely disposed second surface. The outer layer is disposed adjacent to the first surface of the strength layer. The inner layer is disposed adjacent to the second surface of the strength layer.

Abstract: A disclosed example embodiment includes a composite slickline cable having an optical fiber with optimized residual strain. The composite slickline cable includes a fiber reinforced polymer and at least one optical fiber disposed within the fiber reinforced polymer such that axial stress applied to the composite slickline cable is shared by the at least one optical fiber and the fiber reinforced polymer. In the axially unstressed state of the composite slickline cable, the at least one optical fiber has a residual strain between about ?1,000 microstrain and about 500 microstrain.

Abstract: A connector mating system that can enable the coupling and decoupling of electrical or optical communications channels, while in a deep, sub-oceanic, sea-floor environments, during which time the contacting interfaces of the said channels remain fully protected from the destructive effects of the said environment. The system features a Wet-Mate Connector (WMC) that provides a means for electrical, optical and hybrid interconnection within an extremely hostile environments.

Abstract: An illuminable transmission cable includes an electrical conductor, a light-diffusing fiber having a glass core and a cladding, at least one of the glass core and a core-cladding interface having a plurality of scattering structures. The light-diffusing fiber is configured to optically couple with a light source which emits light into the light-diffusing fiber. The scattering structures are configured to scatter the emitted light and output the emitted light along at least a portion of a sidewall of the light-diffusing fiber. A light transmissive jacket surrounds the electrical conductor and the light-diffusing fiber.

Abstract: A fiber optic slickline. The slickline includes fiber optic communication means without full downhole power transmitting capability. Nevertheless, the slickline is configured to accommodate an axial load up to, and in excess of 2,000 lbs. Downhole tools and tool assemblies are configured with opto-electronic interfacing features so as to remain electronically compatible while also taking advantage of fiber optic communications afforded over the slickline. The slickline and tools may be employed in logging and other downhole operations in a manner that provides real time communication with substantially reduced surface equipment expense in terms of footprint and power requirements.

Abstract: A fiber optic cable including an inner guard layer surrounding a core containing at least one optical fiber; and an outer guard layer surrounding the inner guard layer; wherein the inner guard layer includes at least one metal tube with at least one optical fiber inside the tube; and wherein the outer guard layer includes at least one metal tube with at least one optical fiber inside the tube.

Abstract: A cable that includes a first optical fiber in a center, a first layer with a plurality of metal wires and a stainless steel tube surrounding the first optical fiber, a second optical fiber inside the stainless steel tube, and a second layer with a plurality of metal wires surrounding the first layer, wherein the first optical fiber is directly exposed to the outside environment.

Abstract: A breakout cable includes a data-lane module comprising a plurality of data lanes configured to send and receive a plurality of data signals, a plurality of breakout modules, and a plurality cables. Each breakout module is associated with a data lane and each cable interfaces with the data-lane module and a corresponding data lane to send and receive the plurality of signals between the data-lane module and a corresponding breakout module at a nominal 25 Gbps or a nominal 100 Gbps. In various embodiments, the data-lane module connects to a host and each of the plurality of modules connects to one or more system(s) to enable host-to-system(s) communications and system(s)-to-host communications at a nominal 100 Gbps or a nominal 400 Gbps.

Abstract: A power cable assembly device adapted to be arranged in the spaces between neighboring power cores of a power cable, includes an extruded profiled body made of a polymer material and adapted to the cross-sectional shape and elongation of the power cable, the profiled body including a chamber and defining a slit to the chamber, the chamber being adapted to receive a fiber optic cable via the slit. Substantially the whole surface of the profiled body inside the chamber, the surface of the profiled body defining the slit, and the surface of at least a region outside the profiled body extending from the slit and away from the slit is provided with a layer of semi-conductive material.

Abstract: A fiber optic cable includes at least one optical fiber, at least one strength member, armor components, and a cable jacket. The cable jacket has a cavity with a generally rectangular cross-section with the armor components disposed on opposite sides of the cavity.

Abstract: An electrical cable includes a cable jacket extending a length and having an internal passageway that extends along the length of the cable jacket. Twisted pairs of insulated electrical conductors extend within the internal passageway along the length of the cable jacket. Each twisted pair includes two insulated conductors twisted together in a helical manner. At least two optical fibers extend within the internal passageway along the length of the cable jacket. The optical fibers are independently held within the internal passageway of the cable jacket relative to each other.

Abstract: An electrical receptacle connector, provided to connect with an electrical plug connector, includes a metal shell, an insulation housing and a conductive piece. The conductive piece is disposed at a tongue portion of the insulation housing and includes a contact portion, two laterally soldering portions and an abutting portion. The contact portion is disposed at a rear contact region of the tongue portion, the two laterally soldering portions are respectively extending from two sides of the contact portion, and the abutting portion is extending from the contact portion to attach on a base portion of the insulation ho thus abutting against an inner wall of the metal shell.

Abstract: A vehicle component (3, 11) for a motor vehicle body has at least one line (6, 7, 12, 13, 14) integrated in the vehicle component (3, 11). The vehicle component (3, 11) is formed from a fiber composite material and the at least one line (6, 7, 11, 12, 13) is laminated into the vehicle component (3, 11).

Abstract: A hybrid optical fiber cable is disclosed for supplying both signals and power. The hybrid optical fiber cable includes an inner jacket and an outer jacket. Multiple power supply lines and optical fiber signal lines are disposed within the inner jacket. The optical fiber signal lines are used only for transmitting video, data, voice, and/or control signals through the hybrid optical fiber cable. A grounding portion is also provided between the inner jacket and the outer jacket in order to provide a return current path for the hybrid optical fiber cable.

Abstract: A method of measuring the length of an electric cable, includes providing an electric cable having a cable length and including a cable neutral axis, and a fiber unit longitudinally extending along the cable and including an optical fiber arranged substantially along the neutral axis, wherein the optical fiber is mechanically coupled with the cable; injecting an optical signal into the optical fiber; detecting back-scattered light from the optical fiber responsive to the injected optical signal; analyzing the detected back-scattered light as a function of time so as to determine the length of the optical fiber, and deriving the cable length from the length of the optical fiber.

Abstract: In some aspects, polymeric yarns and communications cables incorporating the same are provided herein. Additionally, in some aspects, methods of producing polymeric yarns and communications cables incorporating the same are provided.

Abstract: A breakout cable includes a polymer jacket and a plurality of micromodules enclosed within the jacket. Each micromodule has a plurality of bend resistant optical fibers and a polymer sheath comprising PVC surrounding the bend resistant optical fibers. Each of the plurality of bend resistant optical fibers is a multimode optical fiber including a glass cladding region surrounding and directly adjacent to a glass core region. The core region is a graded-index glass core region, where the refractive index of the core region has a profile having a parabolic or substantially curved shape. The cladding includes a first annular portion having a lesser refractive index relative to a second annular portion of the cladding. The first annular portion is interior to the second annular portion. The cladding is surrounded by a low modulus primary coating and a high modulus secondary coating.

Abstract: In a fiber there is provided a fiber matrix material having a fiber length; and an array of isolated in-fiber filaments that extend the fiber length. The in-fiber filaments are disposed at a radius in a cross section of the fiber that is a location of a continuous filament material layer in a drawing preform of the fiber. As a result, there is provided a fiber matrix material having a fiber length; and a plurality of isolated fiber elements that are disposed in the fiber matrix, extending the fiber length, where the plurality is of a number greater than a number of isolated domains in a drawing preform of the fiber.

Abstract: An optical fiber cable comprises a plurality of optical fibers, tensile strength fibers that accommodate the plurality of optical fibers, and a sheath formed with a thermoplastic resin and covering the tensile strength resin. In this optical fiber cable, when a Young's modulus of the sheath at 0° C. is E [MPa], a cross-sectional area of the optical fiber cable is S [mm2] and an inner diameter of the sheath of the optical fiber cable is Di [mm], ES (0° C.) [N] which is the product of the Young's modulus E at 0° C. and the cross-sectional area S, and the inner diameter Di [mm] satisfy: ES ? ( 0 ? ° ? ? C .

Abstract: A connector mating system that can enable the coupling and decoupling of electrical or optical communications channels, while in a deep, sub-oceanic, sea-floor environments, during which time the contacting interfaces of the said channels remain fully protected from the destructive effects of the said environment. The system features a Wet-Mate Connector (WMC) that provides a means for electrical, optical and hybrid interconnection within an extremely hostile environments.

Abstract: A cable system is disclosed including a central cable; an inner membrane having a higher minimum bend radius than the central cable and surrounding the cable, thereby forming an inner chamber around the central cable, the inner chamber containing a gas or at least one chemical; and an outer membrane surrounding the inner membrane and forming an outer chamber around the inner chamber, the outer chamber comprising a gas or at least one chemical. When the minimum bend radius of the inner membrane is exceeded, the inner membrane fractures or breaks, and the gas or at least one chemical from the inner chamber enters the outer chamber to create a chemiluminescence reaction, color, or smell.

Abstract: A cable component is provided that includes at least one optical fiber; and a two shaped profiles having inner and outer surfaces such that the inner surfaces combine to from an enclosure for the at least one optical fiber, wherein a first of the two shaped profiles has a cross sectional arc that is greater than a cross sectional arc of a second of the two shaped profiles.

Abstract: A method and apparatus for providing a tracer function for networked cable systems used for data or power transmission. A self contained and self powered indicator circuit is described that enables tracing the location of both ends of a networked cable.

Abstract: A hybrid network for in-building wireless (IBW) applications that provides a forward link path and a reverse link path, each on separate media. In particular, a hybrid cabling system for providing wireless coverage in a building comprises a forward link comprising at least one optical fiber to couple a first signal generated at an RF input bank with an RF antenna node, and a reverse link comprising coaxial cable, wherein a portion of the reverse link includes radiating coaxial cable configured to receive a second signal transmitted by a wireless user equipment in the building and pass the second signal to the RF input bank.

Abstract: Hybrid fiber optic cables including one or more electrical coaxial subassembly allowing for fiber movement to reduce attenuation during bending are disclosed. Related connectorized cables and systems are also disclosed. The hybrid fiber optic cables include both one or more coaxial subassembly and optical fibers to provide both optical and electrical connectivity as part of a connectorized system. Use of one or more coaxial subassembly reduces impedance variations and lowers cost. Each coaxial sub-assembly also includes multiple electrical conductors to increase electrical connectivity capacity (e.g., power and signals) of the hybrid cable, as needed or desired. Further, the hybrid cable may include a channel with optical fiber(s) of the hybrid cable disposed therein, free of attachment to the channel. The channel allows the optical fibers to move relative to the cable jacket and control bend radius to reduce optical attenuation when the hybrid fiber optic cable is bent.

Abstract: A resin composition includes a silane-crosslinked polyethylene as a main component provided by crosslinking a polyethylene in the presence of a silanol condensation catalyst and water, the polyethylene being graft-copolymerized with a silane compound by a free radical generating agent. The polyethylene has a density of 0.87 to 0.91 g/cm3. The silane compound is included not less than 2 parts by mass relative to 100 parts by mass of the polyethylene. The resin composition includes silicon detected by a fluorescence X-ray at a rate of not less than 0.3 mass % and has a gel fraction of not less than 70%. A mass ratio of the silane compound to the free radical generating agent is not less than 35 and not more than 150.

Abstract: A communication cable includes one or more conductive elements surrounded by a dielectric sheath. The sheath member has a first dielectric constant value. A dielectric core member is placed longitudinally adjacent to and in contact with an outer surface of the sheath member. The core member has a second dielectric constant value that is higher than the first dielectric constant value. A cladding surrounds the sheath member and the dielectric core member. The cladding has a third dielectric constant value that is lower than the second dielectric constant value. A dielectric wave guide is formed by the dielectric core member surrounded by the sheath and the cladding.

Abstract: An electrical cable includes a cable jacket extending a length and having an internal passageway that extends along the length of the cable jacket. Twisted pairs of insulated electrical conductors extend within the internal passageway along the length of the cable jacket. Each twisted pair includes two insulated conductors twisted together in a helical manner. At least two optical fibers extend within the internal passageway along the length of the cable jacket. The optical fibers are independently held within the internal passageway of the cable jacket relative to each other.

Abstract: A composite optical fiber cable has coated optical fibers and electric wires disposed inside a sheath. The optical fibers are enclosed within a first protective tube that is situated at the cross-sectional center, while the electric wires are disposed between the first protective tube and the sheath, and are capable of moving in the circumferential direction of the first protective tube. A composite optical fiber cable assembly includes a composite optical fiber cable and a connector attached to the cable. Inside the connector, a wiring portion for wiring the optical fiber to a ferrule and a wiring portion for wiring the electric wire to an electric terminal are disposed within a common space S inside a housing, and at least the wiring portion of the optical fiber which lies inside the space S is covered by a second protective tube.

Abstract: A communications cable that has a core that includes a dielectric separator. The separator has a spline that extends longitudinally in the core, thereby dividing the core into at least two quadrants. The separator also has at least one compartment. At least one pair of twisted insulated conductors is received in at least one of the quadrants and at least one optical fiber is received in the compartment of the dielectric separator. An outer jacket substantially surrounds the core.

Abstract: An optical cable includes an optical fiber ribbon core wire provided with an optical fiber having a core and a cladding that surrounds the core, a sheath that surrounds the optical fiber ribbon core wire, and a braid arranged inside the sheath. The braid is formed to include wires woven with each other. In the optical cable, the wire that forms the braid is pushed into the sheath so that the sheath is integrated with the braid.

Abstract: A method for fabricating a coaxial structure having an electrical conductor surrounded by an optically conductive dielectric is disclosed. The method may include creating an optical trench in an electrical conductor and depositing an optical material into the optical trench to cover an inner surface of the trench. The method may also include removing a portion of the deposited optical material from the optical trench to form an embedded trench in the deposited optical material, and building up electrically conductive material from within the embedded trench to create an inner electrical conductor. The method may also include depositing optical material around an exposed portion of the inner electrical conductor to create an optical channel encapsulating the inner electrical conductor, and depositing electrically conductive material over a top surface of the optical channel and over a top surface of the first electrical conductor to create the coaxial structure.

Abstract: A hybrid cable has optical conductors and electrical conductors. The electrical conductors are selected to have varying resistances per unit length, depending upon the distance from a power source at which the conductor is expected to terminate. The use of varying resistance conductors can be used to balance the power supplied to external devices and to lower cable cost, size, and weight.

Abstract: A combined low attenuation optical communication and power cable is provided. The cable includes a cable body having an inner surface defining a channel within the cable body. The cable includes an optical transmission element located within the channel and a copper electrical conducting element located within the channel. The cable includes a plurality of tensile strength yarn stands located within the channel.

Abstract: A hybrid optical fiber cable is disclosed for supplying both signals and power. The hybrid optical fiber cable includes an inner jacket and an outer jacket. Multiple power supply lines and optical fiber signal lines are disposed within the inner jacket. The optical fiber signal lines are used only for transmitting video, data, voice, and/or control signals through the hybrid optical fiber cable. A grounding portion is also provided between the inner jacket and the outer jacket in order to provide a return current path for the hybrid optical fiber cable.

Abstract: A power and/or telecommunication cable (Ia,Ib) includes one or several conductor elements (10,20,30) surrounded by an outer sheath, where the outer sheath (40,50) comprising a first layer (40a, 40b) able to emit light radiation, and a second layer (50) made of a light transmitting thermoplastic polyurethane (TPU) material surrounding the first layer (40a, 40b), so that h first layer (40a, 40b) is visible through the second layer (50).

Abstract: Molded fiber optic cable furcation assemblies, and related fiber optic components, assemblies, and methods are disclosed. In one embodiment, an end portion of a fiber optic cable with a portion of a cable jacket removed to expose optical fibers and/or a cable strength member(s) therein and thereafter placing the cable into a mold for creating a molded furcation plug about the end portion of the fiber optic cable. The furcation plug may be overmolded about the end portion of the fiber optic cable. The molded furcation plug can be used to pull a fiber optic cable without damaging the optical fiber(s) disposed within the fiber optic cable. The molded furcation plug is advantageous since it manufactured with fewer parts, without epoxy, and/or without a labor intensive process that may be difficult to automate.