Abstract: Methods of controlling the position of an optical fiber having a minimum bend radius within an optical fiber channel in a fiber optic cable having a small footprint are disclosed. The position of the optical fibers is controlled so that the fiber is not bent at a radius below its minimum bend radius.

Abstract: Distributed communications systems providing and supporting radio frequency (RF) communication services and digital data services, and related components and methods are disclosed. The RF communication services can be distributed over optical fiber to client devices, such as remote units for example. Power can also be distributed over electrical medium that is provided to distribute digital data services, if desired, to provide power to remote communications devices and/or client devices coupled to the remote communications devices for operation. In this manner, as an example, the same electrical medium used to transport digital data signals in the distributed antenna system can also be employed to provide power to the remote communications devices and/or client devices coupled to the remote communications devices.

Abstract: A hybrid cable includes a jacket defining a cavity therein, a central strength member, a ribbon unit having a plurality of optical fibers, and a conductor cable, wherein the conductor cable and the ribbon unit are stranded around the central strength member to extend through the cavity of the jacket. A method of manufacturing a hybrid optical and power cable includes stranding at least one ribbon unit and at least one conductive power cable around a strength member and extruding a jacket around the stranded at least one ribbon unit and at least one conductive power cable.

Abstract: Distributed antenna systems providing and supporting radio frequency (RF) communication services and digital data services, and related components and methods are disclosed. The RF communication services can be distributed over optical fiber to client devices, such as remote antenna units for example. Power can also be distributed over electrical medium that is provided to distribute digital data services, if desired, to provide power to remote communications devices and/or client devices coupled to the remote communications devices for operation. In this manner, as an example, the same electrical medium used to transport digital data signals in the distributed antenna system can also be employed to provide power to the remote communications devices and/or client devices coupled to the remote communications devices.

Abstract: A hybrid cable includes a cable jacket, elements stranded within the cable jacket, and armor between the elements and the cable jacket. The armor is configured to provide electro-magnetic interference shielding and grounding as well as crush and impact resistance for the hybrid cable. The elements include electrical-conductor elements and one or more fiber-optic elements. The electrical-conductor elements include a metallic conductor jacketed in a polymer, where the electrical-conductor elements are each within the range of 10 American wire gauge (AWG) to 1\0 AWG. The one or more fiber-optic elements include optical fibers within a polymeric tube. At least six of the elements are stranded side-by-side with one another around a central element, which is one of the electrical-conductor elements or one of the one or more fiber-optic elements.

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 large and small diameter optical fiber carrying cable is provided. The cable includes a cable body including an inner surface defining a channel within the cable body, a first group of optical fibers comprising a plurality of first optical fibers located within the channel and a second group of optical fibers comprising a plurality of second optical fibers located within the channel. The optical core diameter of the first optical fibers is larger than the optical core diameter of the second optical fibers.

Abstract: A fiber optic cable includes a polymeric jacket, an optical fiber, and first and second longitudinal strength elements. The jacket defines an outer periphery and a cavity interior thereto. The cavity is elongate and the outer periphery is polygonal. The optical fiber is positioned within the cavity of the jacket. The first and second longitudinal strength elements are embedded in the jacket on an opposite sides of the cavity from one another. The cable resists bending in a non-preferential plane by no more than five times as much as the cable resists bending in a preferential plane.

Abstract: A cable includes a channel with an aspect ratio that houses optical fibers therein. The cable includes first and second stranded conductors on opposing sides of the channel. The channel is arranged with respect to the stranded conductors so that the fibers assume low strain positions in the channel when the cable is bent.

Abstract: A fiber optic cable is disclosed, wherein the cable includes a plurality of optical fibers, a tensile-strength layer, and a protective cover surrounding the tensile-strength layer and having an outside diameter Do?5 mm, wherein under a crush load of 100N/cm for 10 minutes, the optical fibers exhibit a delta attenuation of less than 0.8 decibels at a wavelength of 1300 nanometers. A method of forming a fiber optic cable includes extruding a protective cover longitudinally around a plurality of optical fibers and a tensile-strength layer such that the protective cover has an outside diameter Do?5 mm and the optical fibers exhibit a delta attenuation of less than 0.8 decibels at a wavelength of 1300 nanometers when placed under a crush load of 100N/cm for 10 minutes.

Abstract: A fiber optic cable includes a polymeric jacket, an optical fiber, and first and second longitudinal strength elements. The jacket defines an outer periphery and a cavity interior thereto. The cavity is elongate and the outer periphery is polygonal. The optical fiber is positioned within the cavity of the jacket. The first and second longitudinal strength elements are embedded in the jacket on an opposite sides of the cavity from one another. The cable resists bending in a non-preferential plane by no more than five times as much as the cable resists bending in a preferential plane.

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 crush-resistant fiber optic cable is disclosed, wherein the cable includes a plurality of optical fibers. The fibers are generally arranged longitudinally about a central axis, with no strength member arranged along the central axis. A tensile-strength layer surrounds the plurality of optical fibers. A protective cover surrounds the tensile-strength layer and has an outside diameter DO in the range 3 mm?DO?5 mm.

Abstract: Methods of controlling the position of an optical fiber having a minimum bend radius within an optical fiber channel in a fiber optic cable having a small footprint are disclosed. The position of the optical fibers is controlled so that the fiber is not bent at a radius below its minimum bend radius.

Abstract: A fiber optic jumper cable having a central axis includes a bend-resistant optical fiber generally arranged along the central axis. A tensile-strength layer surrounds the bend-resistant optical fiber. A protective cover surrounds the tensile-strength layer and has an outside diameter DO in the range 1.6 mm?DO?4 mm.

Abstract: A hybrid cable includes a guide in the center of the cable, elements stranded side-by-side with one another around the guide, fiber optic elements including optical fibers, a metal armor, and a polymeric jacket of the cable surrounding the metal armor. The elements stranded side-by-side with one another around the guide include electrical-conductor elements, which themselves include stranded metal wires insulated in a jacket of the electrical-conductor elements. The electrical-conductor elements are round and have the same diameter as one another. Furthermore, the electrical-conductor elements are each within the range of 10 American wire gauge (AWG) to 1\0 AWG. The fiber optic elements may be included in or integrated with the group of elements stranded side-by-side with one another around the guide. The metal armor surrounds the elements stranded side-by-side with one another around the guide, and serves as a grounding conductor and an electro-magnetic interference shield.

Abstract: Micromodule cables include subunit, tether cables having both electrical conductors and optical fibers. The subunits can be stranded within the micromodule cable jacket so that the subunits can be accessed from the micromodule cable at various axial locations along the cable without using excessive force. Each subunit can include two electrical conductors so that more power can be provided to electrical devices connected to the subunit.

Abstract: A hybrid cable includes a cable jacket and elements stranded within the cable jacket. The elements include greater-capacity electrical-conductor elements and sub-assembly elements. The greater-capacity electrical-conductor elements include a metallic conductor jacketed in a polymer, each within the range of 10 American wire gauge (AWG) to 1\0 AWG. The sub-assembly elements include stranded combinations of sub-elements, where the sub-elements include at least one of polymeric tubes comprising optical fibers and lesser-capacity electrical-conductor elements, each having a lesser current-carrying capacity than 10 AWG. The sub-elements are stranded with respect to one another and additionally stranded as part of sub-assembly elements with respect to other elements.

Abstract: Micromodule cables include subunit, tether cables having both electrical conductors and optical fibers. The subunits can be stranded within the micromodule cable jacket so that the subunits can be accessed from the micromodule cable at various axial locations along the cable without using excessive force. Each subunit can include two electrical conductors so that more power can be provided to electrical devices connected to the subunit.

Abstract: A fiber optic drop cable includes an optical fiber, a tight buffer layer on the optical fiber, at least one strength member, and a jacket surrounding the tight buffer layer. The jacket is coupled to the at least one strength member by at least partial embedment of at least one of the strength members in the jacket, which facilitates coupling between the jacket and strength member. The fiber optic drop cable has an average delta attenuation of 0.4 dB or less at a reference wavelength of 1625 nanometers with the fiber optic cable wrapped 2 turns about a 7.5 millimeter diameter mandrel.