A method for the continuous production of coaxial cables (224) having a thin-walled, radially closed outer conductor of nonferrous metal comprises supplying a flat strip of the nonferrous metal to a shaping apparatus (212), wherein the thickness of the strip corresponds to the wall thickness of the coaxial cable. The shaping apparatus is configured to continuously shape the supplied flat strip into a form corresponding to the outer conductor of the coaxial cable and around a cable core supplied before the outer conductor is closed. After the shaping, two opposite edges of the flat strip lie flush against one another in a contact region and are continuously welded to one another by a welding apparatus (216) by means of a laser, which radiates light having a wavelength smaller than 600 nm. The laser heats a point in a welding region that has a diameter smaller than 20% of the cross-sectional dimension of the coaxial cable. The welded coaxial cable is drawn off from the welding region and, after introducing a parallel or helical corrugation, is received in a receiving device (226).

A wire includes an elongate conductive core wire, an elongate insulating layer disposed on and surrounding the elongate conductive core wire, an elongate conductive shield wire disposed adjacent to the insulating layer and the elongate conductive core wire, an elongate conductive shield layer disposed on the insulating layer and on the conductive shield wire such that the elongate insulating layer, the elongate conductive core wire, and the elongate conductive shield wire are embedded in the elongate conductive shield layer, the elongate conductive shield wire being electrically connected to the elongate conductive shield layer.

A dual axial cable includes first and second signal conductors, a shield, and a drain wire. The first and second signal conductors transmit a differential signal. The shield is spirally wrapped around the first and second conductors, and causes a resonant characteristic of the dual axial cable. The drain wire provides a return path for the differential signal in the dual axial cable. The drain wire is roughened to a specific amount of roughness, which reduces signal loss at resonant frequencies of the resonant characteristic caused by the shield.

A production method for a headline sonar cable (20, 120) that exhibits a high breaking-strength and lighter weight than a conventional steel headline sonar cable. Producing the headline sonar cable (20, 120) is characterized by the steps of: a. providing an elongatable internally-located conductive structure (34, 134) that is adapted for data signal transmission; and b. braiding a strength-member jacket layer (52) of polymeric material around the structure (34, 134) while ensuring that the structure (34, 134) is slack when surrounded by the jacket layer (52). The structure (34, 134) of the cable (20, 120) retains conductivity upon stretching of the jacket layer (52) surrounding the structure (34, 134) that lengthens the cable (20, 120). For one embodiment of the method a conductor (20) wrapped around a rod (24) and enclosed within a sheath layer (32) forms the structure (34, 134). For another embodiment of the method a braided conductor (122) enclosed within a braided sheath (124) and a polymeric layer (132) forms the structure (34, 134).