A computer-readable, non-transitory medium storing a program that causes a computer to execute a process is provided. The process includes acquiring a backward Rayleigh scattered light from an optical fiber composite overhead ground wire provided along an electrical power transmission line, determining each of spectral densities of each of frequencies of vibration of the optical fiber composite overhead ground wire, on a basis of the backward Rayleigh scattered light, estimating a wind speed of a wind hitting the electrical power transmission line, on a basis of a first spectral density of a first frequency band including a natural frequency of the optical fiber composite overhead ground wire, and estimating a wind direction of the wind, on a basis of a second spectral density of a second frequency band which does not include the natural frequency of the optical fiber composite overhead ground wire.

Various examples are provided related to optical ground wire (OPGW) designs and mitigation of impulse effects. In one example, an optical ground cable includes one or more inner optical fiber; and a shield surrounding the one or more inner optical fiber. The shield includes a shield material have a skin-depth less than a skin-depth of aluminum which can improve rejection of intrusive signals and communications capabilities. Conductivity of the shield material can be greater than the conductivity of aluminum and permeability of the shield material can be greater than the permeability of aluminum.

The present invention provides an optical fiber cable (100) having a plurality of optical waveguides (102), one or more cylindrical retaining elements (104) housing the plurality of optical waveguides (102), a sheath (106) enclosing the one or more cylindrical retaining elements (104) and embedded strength members (108). In particular, the one or more cylindrical retaining elements (104) has a filling coefficient between 0.5 to 0.8. And, the filling coefficient is a ratio of cross-sectional area of the plurality of optical waveguides (102) inside a cylindrical retaining element (104) and inner cross-sectional area of the cylindrical retaining element (104). The ratio of breaking load of a cylindrical retaining element (104) to an embedded strength member (108) is less than or equal to 1.

A passive optical network includes a central office providing subscriber signals; a fiber distribution hub including an optical power splitter and a termination field; and a drop terminal. Distribution fibers have first ends coupled to output ports of a drop terminal and second ends coupled to the termination field. A remote unit of a DAS is retrofitted to the network by routing a second feeder cable from a base station to the hub and coupling one the distribution fibers to the second feeder cable. The remote unit is plugged into the corresponding drop terminal port, for example, with a cable arrangement having a sealed wave division multiplexer.

The clamping device may include (1) a monitoring device for a powerline conductor, where the monitoring device includes (a) at least one detection component that detects at least one physical characteristic at a location of the monitoring device, (b) a transmitter that wirelessly transmits data indicating the at least one physical characteristic, and (c) a receiver that wirelessly receives data indicating the at least one physical characteristic from at least one other monitoring device, where the transmitter retransmits the data indicating the at least one physical characteristic from the at least one other monitoring device, and (2) a container that retains the monitoring device such that one or more of the at least one detection component is maintained proximate the powerline conductor. The clamping device clamps a fiber optic cable to the powerline conductor to restrict movement of the fiber optic cable relative to the powerline conductor.

It is disclosed a process and an apparatus for manufacturing a figure of eight cable. An extrusion head has separate extrusion dies extruding in parallel a first and second outer sheath around a first and second core, respectively, so as to provide two separate cable elements having respective longitudinal axes laying in a first plane. While the outer sheaths are in a softened state, the cable elements are passed in parallel through a twisting die which causes their longitudinal axes to lay in a second plane forming a predetermined twisting angle with respect to the first plane. This twisting causes the outer sheaths to join together, thereby forming a figure of eight cable.

The clamping device may include (1) a monitoring device for a powerline conductor, where the monitoring device includes (a) at least one detection component that detects at least one physical characteristic at a location of the monitoring device, (b) a transmitter that wirelessly transmits data indicating the at least one physical characteristic, and (c) a receiver that wirelessly receives data indicating the at least one physical characteristic from at least one other monitoring device, where the transmitter retransmits the data indicating the at least one physical characteristic from the at least one other monitoring device, and (2) a container that retains the monitoring device such that one or more of the at least one detection component is maintained proximate the powerline conductor. The clamping device clamps a fiber optic cable to the powerline conductor to restrict movement of the fiber optic cable relative to the powerline conductor.

The present disclosure describes a grommet formed of a polymeric material and adapted for bundling a plurality of discrete cables, comprising a main body having a generally cylindrical profile surrounding an interior cavity, the main body further having a length, a thickness, and a longitudinal axis; and a central member integrally coupled to the main body and located within the interior cavity of the main body, the central member extending generally parallel to the longitudinal axis of the main body. Methods of bundling cables are also provided.

An aerial cable management device includes a trunk; and a plurality of arms, each arm including a body defining a central pivot point and having a cable support element disposed at both opposite ends of the body, wherein each of the plurality of arms is rotatably coupled with the trunk in a shared direction of rotation.

A device for installing an all fiber optoelectrical transducer on the base of a pin insulator column, such that the device mounts to the insulator pin column in a bushing style of concentric attachment and enables retrofits of said device to existing transmission & distribution bushing insulator equipment. A rigid and solid mechanical support region contains a hollow bushing attachment point at a center location, and radiates outward and bonds solidly and statically to a hollow toroidal conduit, which houses optical wave guides, terminating at auxiliary connection ports, located on the exterior of the hollow toroidal conduit region, while hollow conduit support arms extend from the exterior conduit ring to a power conductor region, and integrate with optical connection ports located on static support stands, where the optical ports interface with a detachable and flexible fiber loop transducer, which surrounds an energized power conductor.