A high-speed transmission line includes a first shielded layer, a first insulating layer, a conductor layer, a second insulating layer and a second shielded layer sequentially attached to each other. The conductor layer includes plural first conductors and plural first conductors interspersed with each other, and the first conductor has a round cross section and is made of a round copper wire.

A connecting object is used for connection to a device. The connecting object has a sheet-like shape. The device has at least two ground pins and at least one signal pin. The at least one signal pin is arranged between two of the ground pins in a pitch direction. The connecting object has a wiring layer, a shield layer and an insulator. The wiring layer is formed with only a signal line which is configured to be connected with the signal pin. The wiring layer is formed with no ground line which is configured to be connected with the ground pin. The shield layer covers the wiring layer via the insulator which is positioned between the shield layer and the wiring layer.

A data transmission cable includes a plurality of juxtaposed wires, a plastic layer enclosing on the wires integrally and a metallic shielding layer arranged on an outer side of the plastic layer. The metallic shielding layer has a length matching the data transmission cable and a width greater than the circumferential extension length of the data transmission cable, two ends of the metallic shielding layer in a width direction are compacted and bonded to each other on one side of the data transmission cable in the width direction, to form a shielding portion covering the plastic layer and a compacting portion connected to one side of the shielding portion.

A shielded flat cable includes a plurality of flat conductors arranged in parallel, a pair of resin insulating layers sandwiching the flat conductors from both sides of a parallel surface of the flat conductors, and covering portions other than end portions of the flat conductors in a length direction, a pair of shield layers in contact with an outer surface of at least one resin insulating layer of the pair of resin insulating layers, and a pair of first resin films with an adhesive covering an outer surface of the pair of resin insulating layers or the shield layer. A dielectric loss tangent of the resin insulating layer, of the pair of resin insulating layers, in contact with the shield layer is 0.001 or less at 10 GHz, and the adhesive or the pair of first resin films is made of a flame retardant material.

A ribbon cable is described, including a plurality of conductors extending along a length of the cable, and a structured insulative tape comprising a plurality of spaced apart supports forming alternating first and second groups of supports disposed on a major surface of the structured insulative tape. Each first group of supports includes at least one taller first support, and each second group of supports includes at least one shorter second support. The insulative tape is helically wrapped around the plurality of conductors along the length of the cable such that each first group of supports is disposed between and maintains a minimum separation between two adjacent conductors, and each second group of supports is disposed around one or more conductors to maintain spacing between the conductors and an outer surface of the ribbon cable.

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 automated assembly sensor cable has a generally wide and flat elongated body and a registration feature generally traversing the length of the body so as to identify the relative locations of conductors within the body. This cable configuration facilitates the automated attachment of the cable to an optical sensor circuit and corresponding connector. In various embodiments, the automated assembly sensor cable has a conductor set of insulated wires, a conductive inner jacket generally surrounding the conductor set, an outer jacket generally surrounding the inner jacket and a registration feature disposed along the surface of the outer jacket and a conductive drain line is embedded within the inner jacket. A strength member may be embedded within the inner jacket.

A cable is described, including a plurality of substantially parallel conductors extending along a length of the cable and generally lying in a plane of the conductors, and a dielectric film comprising a plurality of pairs of structures, and folded upon itself along a longitudinal fold line so that the structures in each pair of structures face, and are aligned with, each other, each conductor of the plurality of conductors disposed between the structures in a corresponding pair of structures.

A lower insulating layer 122 bonded on lower surfaces 112 of conductors 110, a lower dielectric layer 132 bonded on a lower surface 122a of the insulating layer 122, a lower shield layer 142a bonded on a lower surface 132a of the lower dielectric layer 132, a terminal T in which the conductors 110 are exposed at an end in a longitudinal direction, a reinforcing plate 160 bonded on the lower surface 122a of the lower insulating layer 122 and the lower surfaces 112 of the conductors 110 at the terminal T, and a grounding member 170 bonded on a lower surface 162 of the reinforcing plate 160 and a lower surface 142a of the lower shield layer 142 to be electrically coupled to the lower shield layer 142 are provided, wherein the grounding member 170 extends to under the terminal T.

With respect to a connector for attachment to a shielded flat cable including a signal wire and a ground wire arranged in parallel, an insulating layer covering the signal wire and the ground wire; and a first shield layer and a second shield layer respectively covering both sides of the insulating layer, wherein a terminal in which the signal wire and the ground wire are exposed is formed on a first shield layer side at an end in a longitudinal direction, the connector includes a casing, wherein the casing includes a bottom to face the first shield layer or the second shield layer, a top to face the first shield layer or the second shield layer, a side wall connected to the bottom and the top, a signal wire contact member, a ground wire contact member, and the connector further includes a signal wire contact member configured to come in contact with the signal wire of the terminal upon the shielded flat cable being attached, a ground wire contact member configured to come in contact with the ground wire of the terminal upon the shielded flat cable being attached, a first shield layer contact member configured to come in contact with the first shield layer upon the shielded flat cable being attached, and a second shield layer contact member configured to be electrically coupled to the second shield layer upon the shielded flat cable being attached, wherein the ground wire contact member is electrically coupled to the first shield layer contact member.