A cable having a plurality of conductors, wherein one or more of the conductors is connected to a receptacle connector built into a main cable trunk of the cable, and wherein one or more of the conductors continues in the cable past the receptacle connector.

This document describes techniques and devices for preventing false positives with an interactive cord. An interactive cord includes a cable, and fabric cover that covers the cable. The fabric cover includes one or more conductive threads woven into the fabric cover to form one or more capacitive touchpoints which are configured to enable reception of touch input that causes a change in capacitance to the one or more conductive threads. A controller, implemented at the interactive cord or a computing device coupled to the interactive cord, can detect the change in capacitance and trigger one or more functions associated with the one or more capacitive touchpoints. In one or more implementations, the interactive cord is designed to prevent false positives which may occur from accidental contact with the touchpoints, such as when the interactive cord makes contact with the user's body or a conductive surface.

Improvements are disclosed to lighting fixtures adjusted in beam direction during use, both manually and remotely by an operator. The head of the manual fixture is mounted rotatably between two standards, which are attached to a base, such that the attachments can be moved vertically along the standards to adjust the distance between the head and base. The remote fixture uses a two-axis mirror for beam direction and at least one additional axis of adjustment. Improvements to power and data distribution and pre-rig truss are disclosed.

There is described herein a harness (106) that remains neutral until configured by a configuration device (110). Wires that connect to specific pins responsible for the configuration of a system are taken out and connected to a configuration port (108) on the harness (106). The configuration port (108), when mated with the configuration device (110), sets a configuration setting of the system. The configuration device (110) may be used to set the power and/or signal parameters of the harness (106) for a system or to configure various options within the system itself or another system.

A cable may include a plurality of twisted pairs of individually insulated conductors, a separator positioned between the twisted pairs, and a jacket formed around the twisted pairs and the separator. The separator may include a longitudinally extending spine positioned between the plurality of twisted pairs, and at least one prong respectively extending from the spine at each of a plurality of longitudinally spaced locations. Additionally, for each pair of adjacent longitudinally spaced locations, the at least one prong extending at a first of the pair of locations may extend in a first set of one or more directions and the at least one prong extending at a second of the pair of locations may extend in a second set of one or more directions that is different than the first set of one or more directions.

A low loss cable system adapted for use as a cable landfall system. The cable system comprises a cable having a plurality of cores. Each core comprises a conductor, a first insulating layer, a second electrically conductive layer and a third layer. The cable comprises two sections, connected at a connection point CP. A first section of the cable is arranged to be exposed to a landfall area and a second section of the cable is arranged to be exposed to a submarine area. The cable is arranged such that circulating currents are prevented or reduced in the second conductive layers of the cable in the section exposed to the landfall area, thus assisting in maintaining the ampacity of the cable in this section without, or by reducing, the need to increase the cross sectional area of the cable in the landfall area. This is accomplished by electrically connecting the second conductive layers of the cores to each other at the connection point. At a distal end of the first section of the cable, the second layers are arranged to leave an open ended termination, thus avoiding a closed circuit that would otherwise create circulating currents in the second layers of the first section, thus maintaining ampacity.

This document describes interactive cords. An interactive cord includes a cable, and fabric cover that covers the cable. The fabric cover includes one or more conductive threads woven into the fabric cover to form one or more capacitive touchpoints which are configured to enable reception of touch input that causes a change in capacitance to the one or more conductive threads. A controller, implemented at the interactive cord or a computing device coupled to the interactive cord, can detect the change in capacitance and trigger one or more functions associated with the one or more capacitive touchpoints. For example, when implemented as a cord for a headset, the controller can control audio to the headset, such as by playing the audio, pausing the audio, adjusting the volume of the audio, skipping ahead in the audio, skipping backwards in the audio, skipping to additional audio, and so forth.

A cable assembly suitable for distributing both power and low voltage control signals to a plurality of discrete devices is disclosed. Power and control signal input plugs are attached by cable to a housing. A first set of power and control signal output connectors is attached by flexible cable to the same housing. A second set of power and control signal output connectors is attached to the housing. Corresponding contacts of all three power connectors and of all three control signal connectors having the same function are made electrically common, such that power and control signals applied to the plugs are available at both output connectors. The structure reduces the number of components and connections required to share power and data relative to prior art methods.

A flexible flat cable and a method of manufacturing the flexible flat cable, may include an insulating film forming an external appearance of the flexible flat cable; a conductor disposed inside the insulating film; and an adhesion layer configured to bond the insulating film to the conductor, wherein the adhesion layer contains metal particles, and when a crack occurs in the conductor, the metal particles connect the conductor in which the crack occurs.

A wire harness that has a relatively simple structure, is highly versatile, and includes a conductive portion that can be electrically connected to a device that is located midway along the routing path. A wire harness includes a conductive portion extending along a routing path to form a circuit. The conductive portion is formed of a single-core wire or a pipe. A branch connection portion configured to be flat against a portion of the conductive portion that is adjacent thereto is provided in the conductive portion midway in an extension direction thereof. A branching wire is connected to the branch connection portion.