A wiring member includes a first wire-like transmission member and a second wire-like transmission member arranged in parallel to each other and a sheet to which the first wire-like transmission member and the second wire-like transmission member are fixed. At least one of the first wire-like transmission member or the second wire-like transmission member includes the plurality of first wire-like transmission members or the plurality of second wire-like transmission members. The sheet includes a first portion to which the first wire-like transmission member is fixed and a second portion to which the second wire-like transmission member is fixed. The first portion is folded back to the second portion, and an edge portion of the first portion and an edge portion of the second portion are fixed to each other at a side opposite to a folded portion where the sheet is folded back.

A wiring member includes a first sheet including a fusion layer, a second sheet, and at least one first wire-like transmission member provided between the first sheet and the second sheet. The first sheet and the second sheet are fixed to each other via the fusion layer in a direction intersecting with a longitudinal direction of the first wire-like transmission member.

The present disclosure relates to a monolithic thin-film lead assembly and methods of microfabricating a monolithic thin-film lead assembly. Particularly, aspects of the present disclosure are directed to a monolithic thin-film lead assembly that includes a cable having a proximal end, a distal end, a supporting structure that extends from the proximal end to the distal end, and conductive traces formed on a portion of the supporting structure. The supporting structure includes one or more layers of dielectric material. The monolithic thin-film lead assembly further includes an interface formed on the supporting structure at the distal end of the cable. The interface includes electrodes and/or sensors in electrical connection with the conductive traces, and the supporting structure has at least one curved portion disposed between a first set of electrodes and a second set of electrodes, and/or between a first set of sensors and a second set of sensors.

An object is to provide a technique capable of easily identifying a type of a wiring member. A wiring member includes: a base member having a holding surface; and at least one wire-like transmission member held on the holding surface, wherein at least one missing wire-like transmission member identification mark indicating at least one missing wire-like transmission member position is provided on the holding surface.

A wiring member includes: a wire-like transmission member; a sheet member including a main surface on which the wire-like transmission member is disposed; and at least one adhesive tape member whose one main surface is an adhesive surface. The at least one adhesive tape member surrounds the wire-like transmission member in a state where the adhesive surface faces toward the wire-like transmission member. The at least one adhesive tape member extends outward from the wire-like transmission member and is adhered to the sheet member with interposition of the adhesive surface.

An object is to provide a technique capable of simply fixing a wire-like transmission member to a sheet regardless of a type of the wire-like transmission member. A wiring member includes a sheet, a holding member fixed to the sheet, and a first wire-like transmission member held by the holding member. The bolding member includes a holding part in which a groove and a protrusion narrowing a width dimension of an opening part of the groove are formed. The first wire-like transmission member is housed in the groove.

To provide a coaxial flat cable that can achieve stable high-frequency transmission characteristics as a structure by which stress is not applied to a specific coaxial cable, even due to handling of the coaxial flat cable or the like. The above-described problem is solved by a coaxial flat cable (20) comprising a plurality of coaxial cables (10) disposed side by side in a width direction (X), and a resin tape (11) integrating at least terminal parts (21) of these coaxial cables (10) from one surface or both surfaces, each of the plurality of coaxial cables (10) being connected by soldering to a substrate (30) or a connector. The resin tape (11) positioned at the terminal parts (21) is configured to be provided with a fixed part (21a), to be fixed to the substrate or the connector, at both end portions in the width direction (X).

An electrical connecting element includes a stretchable insulation sheet, two or more first conductive threads on one surface of the insulation sheet, and two or more first resin threads on the one surface of the insulation sheet. The first conductive threads extend in a predetermined direction and are disposed in parallel with each other orthogonally to the predetermined direction. The first resin threads have thermal adhesiveness. The first resin threads do not overlap with any of the first conductive threads.

A wiring component includes a first wiring portion including a plurality of wirings arranged side by side in a first direction, a second wiring portion including a plurality of wirings arranged side by side in a second direction, and a coupling portion configured to couple the first wiring portion and the second wiring portion to each other, wherein an angle formed by the first direction and the second direction is changeable by deformation of the coupling portion.

A wiring member includes a sheet, a first wire-like transmission member fixed to the sheet, and a second wire-like transmission member having lower rigidity than the first wire-like transmission member and fixed to the sheet. An intersection part of the first wire-like transmission member and the second wire-like transmission member is provided on the sheet, and the first wire-like transmission member is located closer to a side of the sheet than the second wire-like transmission member in the intersection part.