A twin axial cable includes a pair of wires each with a core conductor; a first dielectric extruded around each of the core conductors, said pair of conductors with the first dielectrics being intimately side by side positioned with each other in a transverse direction; a second dielectric different form the first dielectric and extruded around the first dielectrics; a shielding layer enclosing the second dielectric; and a heat seal PET layer enclosing the shielding layer. A coupling ratio which is calculated by a value of an even mode characteristic impedance subtracted an odd mode characteristic impedance divided by a value of the even mode characteristic impedance pulsed the odd mode characteristic impedance is between 15% to 30%.

A data cable has a specially arranged and embodied shielding foil. The shielding foil surrounds an insulated conductor and has multiple layers, including a conductive layer and at least one carrier layer on which the conductive layer is applied. The shielding foil is folded and has a fold around which the conductive layer is guided so that the conductive layer forms an upper face and a lower face. The shielding foil is wound around the insulated conductor. The shielding foil has multiple sequential windings that overlap in an overlap region in which the upper face in one of the multiple sequential windings makes contact with the lower face of a following one of the multiple sequential windings so as to form a continuous shielding configuration.

A shielded electrical cable includes conductor sets extending along a length of the cable and spaced apart from each other along a width of the cable. First and second shielding films are disposed on opposite sides of the cable and include cover portions and pinched portions arranged such that, in transverse cross section, the cover portions of the films in combination substantially surround each conductor set. An adhesive layer bonds the shielding films together in the pinched portions of the cable. A transverse bending of the cable at a cable location of no more than 180 degrees over an inner radius of at most 2 mm causes a cable impedance of the selected insulated conductor proximate the cable location to vary by no more than 2 percent from an initial cable impedance measured at the cable location in an unbent configuration.

An electrical ribbon cable (110) includes an insulated conductor (114) extending along a longitudinal axis of the cable. The cable also includes a shielding film (116) that carries the insulated conductor (114). The shielding film (116) has a variable thickness defining a thickened rib portion (117) and a thinned connecting portion (118), these portions being electrically conductive and extending along the longitudinal axis. The insulated conductor (114) is disposed proximate the rib portion (117). The insulated conductor (114) may be one of multiple insulated conductors that are organized into multiple conductor sets (112) including at least a first and second conductor set, each conductor set (112) including one or more of the insulated conductors (114), and the rib portion (117) may be disposed between the first and second conductor sets.

A cable, such as a USB cable, having at least two pairs of strands, each of which is designed to transmit a differential data signal; in the longitudinal direction (L) of the cable, the at least two pairs of strands extend helically about a common braiding center.

The present invention generally relates to a data communication cable (100) comprising: a set of elongated bodies (102) each formed from an elastic material and having an unextended free length; and for each elongated body (102), a set of conductive wires (104) disposed along the elongated body (102), such that each conductive wire (104) is extendable to more than the free length of the elongated body (102), wherein at least one conductive wire (104) is configured for communicating data between electronic devices; and wherein the conductive wires (104) are extendable in response to extension of the elongated body (102), such that the extended data communication cable (100) remains useable for said data communication between the electronic devices.

A data cable, which is particularly suitable for the automotive industry, is cost-effective to produce and allows high transmission frequencies into the gigahertz range. The data cable has two wire pairs which each have two wires which are surrounded by a pair shield. In addition to the pair shield, a planar or flat shielding element which does not surround the core pairs and makes contact with the two pair shields is arranged between the wires. The shielding element has, in particular, individual wires which run next to one another. Contact can advantageously be made with the pair shield in a plug region in a simple manner by way of the shielding element.

A data cable has a specially formed stranded conductor, as a result of which the transmission properties of the data cable are significantly improved. The stranded conductor is surrounded by insulation and has an unpressed assembly composed of a plurality of individual wires which are of a same type and being embodied as external wires and being disposed around a center. The external wires are embodied with a non-round cross section, with a result that when viewed in cross section an extent of the external wires increases radially outward from the center.

Disclosed is a high-frequency cable, in particular, a high-frequency cable with a stable structure, including: two signal cables arranged in parallel; one ground cable located between the two signal cables or two ground cables respectively located on lateral sides of the two signal cables, and axes of the two signal cables and axes of the two ground cables being located on the same plane; a fastening layer wrapped outside the two signal cables and the ground cable, and configured to fasten the two signal cables and the ground cable; a shielding layer wrapped outside the fastening layer; and a sheath layer wrapped on the shielding layer. The high-frequency cable with a stable structure provided by the present disclosure features a stable structure, is easy to process, reduces production costs, and provides good electrical performance.

A shielded cable includes signal wires each having a signal conductor covered by an insulator, and a shield conductor comprising a metal foil resin tape spirally and overlappingly wrapped around the two signal wires, wherein an edge portion of the metal foil resin tape is folded back so that the metal foil therein is oriented outward, thereby bringing metal foils, which are arranged on lower and upper sides in the overlapping part of wrapping of the metal foil resin tape, into electrical contact with each other. The shielded cable includes two drain wires provided outside the metal foil resin tape and configured to be in electrical contact with an exposed part of the outwardly folded-back metal foil, which is exposed out of the overlapping part.