A method according to the teachings of the present disclosure may include disposing a sheath around a conductor assembly, with an outer surface of the sheath defining spaced apart crowns and valleys. An outlet of at least one ink jet print head may be positioned adjacent the sheath at an angle of 60 degrees to 120 degrees with respect to a longitudinal axis of the sheath. The method may also include using at least one ink jet print head to print marking indicia on the sheath, the marking indicia indicating at least characteristic of the electrical cable assembly.

The present disclosure relates to a color-coded cable identification assembly and a cable. The cable identification assembly comprises: a support element including a fixing element adapted to fix the support element to a cable; and a plurality of identification elements, which are detachably mounted on the support element with the cable being located between the support element and the plurality of identification elements. Each identification element has a predetermined color so that the plurality of identification elements are capable of forming a predetermined color code to identify the cable. The cable identification assembly according to the present disclosure can be very easily and rapidly mounted to the cable, thereby greatly saving the installation time of workers and thus reducing the labor cost and the chance of making a mistake. Compared with a conventional adhesive tape, the cable identification assembly according to the present disclosure can meet the requirements such as anti-ultraviolet, anti-aging and reuse, thereby further reducing the cost of the cable identification assembly.

Systems and methods for physical cable route tracing are provided. In one embodiment, a cable comprises: one or more of either electrical conductors or optical fibers; a cable sheath around the one or more of either electrical conductors or optical fibers; and a pattern of cable tracing facilitation markings located on an exterior of the cable sheath; wherein the cable tracing facilitation markings comprise either: a visually varying pattern that gradually changes along a length of the cable sheath; or a series of coded markings of an ordered sequence pattern.

Systems and methods for physical cable route tracing are provided. In one embodiment, a cable comprises: one or more of either electrical conductors or optical fibers; a cable sheath around the one or more of either electrical conductors or optical fibers; and a pattern of cable tracing facilitation markings located on an exterior of the cable sheath; wherein the cable tracing facilitation markings comprise either: a visually varying pattern that gradually changes along a length of the cable sheath; or a series of coded markings of an ordered sequence pattern.

An adapting cable structure includes a cable, a first circuit board and a second circuit board. The cable is used to transfer a power signal or a control signal. The first circuit board includes a plurality of contacting parts and a plurality of first welding parts. Another end of the cable is on the second circuit board and the plurality of the contacting parts are located at two sides of the first circuit board. The plurality of welding parts are connected to one end of the cable. Furthermore, a pattern of a text or a specific design is placed on the cable. The pattern is used to improve the appearance or the identification of the cable.

A gripping element for arrangement on a component, wherein the component, in particular a cable harness, is of flexible design and has a changeable form, wherein the gripping element has at least one optically detectable marker via which a spatial orientation of the gripping element is detectable by an optical recognition device, and wherein the gripping element is grippable by a gripper.

A method according to the teachings of the present disclosure may include disposing a sheath around a conductor assembly, with an outer surface of the sheath defining spaced apart crowns and valleys. An outlet of at least one ink jet print head may be positioned adjacent the sheath at an angle of 60 degrees to 120 degrees with respect to a longitudinal axis of the sheath. The method may also include using at least one ink jet print head to print marking indicia on the sheath, the marking indicia indicating at least characteristic of the electrical cable assembly.

A wiring harness (1010), a motor vehicle component (1000), a mold (15) for manufacturing a wiring harness (1010), a mold system (10) and a method for manufacturing the wiring harness (1010), the wiring harness (1010) comprising at least one bunch (1020) of at least two cables (1025) and a sheath (1030), at least some sections of the bunch (1020) of cables being embedded in the sheath (1030).

A sensing system for identification of at least one cable is provided. The sensing system includes a transceiver and a controller. The transceiver is configured to transmit mmWave signals and receive reflected mmWave signals. The controller is in communication with the transceiver. The controller is configured to direct the transceiver to transmit the mmWave signals. The controller is further configured to process the reflected mmWave signals and identify highly reflective-to-mmWave material identification markings associated with the at least one cable from the processed reflected mmWave signals.

A sensing system for identification of at least one cable is provided. The sensing system includes a transceiver and a controller. The transceiver is configured to transmit mmWave signals and receive reflected mmWave signals. The controller is in communication with the transceiver. The controller is configured to direct the transceiver to transmit the mmWave signals. The controller is further configured to process the reflected mmWave signals and identify highly reflective-to-mmWave material identification markings associated with the at least one cable from the processed reflected mmWave signals.