A communication system is included in a work string. The communication system includes a communication cable and a crimp sleeve. The communication cable has a housing with a communication line and a metal tube therein, a free line end of the communication line and a free tube end of the metal tube extending from an open end of the housing. The crimp sleeve includes a first sleeve section having a first inner diameter configured to receive the open end of the housing, a second sleeve section having a second inner diameter configured to receive the free tube end of the metal tube, and an opening configured to allow the free line end of the communication line to pass out of the crimp sleeve.

A novel data cable achieves good transmission quality in automotive Internet applications. The data cable has a transmission core with only a single stranded conductor pair or four conductors stranded together to form a quad. The transmission core is surrounded by a jacket having a high air content. The jacket may be a foamed sheath, or alternatively at least one spacer element that defines an annular sheath space with air gaps around the transmission core.

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.

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.

The present disclosure provides a cable connector assembly that includes a cable having conductors secured to contact pads formed on a printed circuit board. A housing and cover are configured to be secured together and combine to form a cavity for receiving the printed circuit board and the cable. A slug is formed around a portion of the cable. Upon assembly of the cover to the housing, the slug is disposed in a pocket formed in the cavity and helps secure the cable to the housing and cover.

Provided are flexible hybrid interconnect circuits and methods of forming thereof. A flexible hybrid interconnect circuit comprises multiple conductive layers, stacked and spaced apart along the thickness of the circuit. Each conductive layer comprises one or more conductive elements, one of which is operable as a high frequency (HF) signal line. Other conductive elements, in the same and other conductive layers, form an electromagnetic shield around the HF signal line. Some conductive elements in the same circuit are used for electrical power transmission. All conductive elements are supported by one or more inner dielectric layers and enclosed by outer dielectric layers. The overall stack is thin and flexible and may be conformally attached to a non-planar surface. Each conductive layer may be formed by patterning the same metallic sheet. Multiple pattern sheets are laminated together with inner and outer dielectric layers to form a flexible hybrid interconnect circuit.

Provided are flexible hybrid interconnect circuits and methods of forming thereof. A flexible hybrid interconnect circuit comprises multiple conductive layers, stacked and spaced apart along the thickness of the circuit. Each conductive layer comprises one or more conductive elements, one of which is operable as a high frequency (HF) signal line. Other conductive elements, in the same and other conductive layers, form an electromagnetic shield around the HF signal line. Some conductive elements in the same circuit are used for electrical power transmission. All conductive elements are supported by one or more inner dielectric layers and enclosed by outer dielectric layers. The overall stack is thin and flexible and may be conformally attached to a non-planar surface. Each conductive layer may be formed by patterning the same metallic sheet. Multiple pattern sheets are laminated together with inner and outer dielectric layers to form a flexible hybrid interconnect circuit.

Various aspects of the present disclosure are directed toward methods and apparatus that include a lead frame with a fixed external pin pitch. A differential signal path is provided that is characterized by bond-pad pitch range, wire length and wire diameter. The differential signal path carries signals in a frequency range between 5 GHz and 16.1 GHz with less than about 25 dB differential return loss (DDRL). Further, the signals are processed at a signal-processing node that is electrically coupled to the differential signal path by using the differential signal path to carry signals in a frequency range between 5 GHz and about 16.1 GHz.

The present invention relates to a data cable. An embodiment of the data cable comprises at least one wire pair and an internal element. The at least one wire pair has two wires running parallel in the longitudinal direction of the data cable. The internal element has at least one flat section. The at least one wire pair and the internal element are arranged in the data cable in such a way that the at least one wire pair lies against the at least one flat section of the internal element.

A signal transmission cable includes a signal line, an insulation layer covering the signal line, and a shield layer covering the insulation layer. A first oxygen amount A.sub.1 on an outer peripheral surface of the insulation layer is 1.2 times or greater than a second oxygen amount A.sub.2 inside the insulation layer, or a contact angle on the outer peripheral surface the insulation layer is 130° or less, or an adhesion-wetting surface energy on the outer peripheral surface the insulation layer is 27 mJ/m.sup.2 or greater, or a first amount of a hydroxy group on the outer peripheral surface of the insulation layer is greater than a second amount of a hydroxy group inside the insulation layer.