A flex flat cable (FFC) is proposed. The FFC comprises a plurality of first signal transmitting lines arranged in parallel with one another. Each of the plurality of first signal transmitting lines comprises a first transmitting conductor configured to transmit a signal, a first insulating layer enclosing the first transmitting conductor, and a second insulating layer, enclosing the first insulating layer. The FFC further includes a first insulating coat enclosing the plurality of first signal transmitting lines, a first ground conductor arranged at one side of the first insulating coat and configured to be grounded, a metallic shielding layer enclosing the first insulating coat and the first ground conductor and a second insulating coat enclosing the metallic shielding layer, and a second insulating coat enclosing the metallic shielding layer.

The first ground conductor contacts the metallic shielding layer.

A medical coaxial connector includes: an internal conductor configured to be electrically connected to an other-side inner conductor when the medical coaxial connector is connected to an other-side medical coaxial connector; an outer conductor electrically connected to the inner conductor, formed in a tubular shape surrounding the inner conductor, and configured to be electrically connected to an other-side outer conductor when the medical coaxial connector is connected to the other-side medical coaxial connector; and an insulating body that is placed on inner periphery side of the outer conductor and formed in a cylindrical shape surrounding the inner conductor. The insulating body is configured to be placed on inner periphery side of the other-side outer conductor and a leading end of the insulating body in a connection direction toward the other-side coaxial connector is configured to protrude more in the connection direction than the inner conductor.

A wafer connector is disclosed in which a plurality of twin-axial wires are terminated to the tails of ground and signal terminals of the connector. Each twin-axial wire includes a pair of signal wires enclosed in a conductive sheath. A conductive grounding clamp is provided that contacts the sheaths of the twin-axial wires and holds them together as a unit to facilitate the attachment of the wires to the connector terminal tails. The clamp has two opposing halves that cooperatively define openings which receive the twin-axial wires and flat, interconnecting portions extending between the openings that provide contact points where the grounding clamp may be attached to the connector terminal tails.

A plug connector assembly includes a cable and a mating member electrically connected to the cable, the mating member having an insulative housing and a contacting module retained in the insulative housing, the contacting module having a first contacting module unit and a second contacting module unit, the first contacting module unit having plural first contacts arranged along a lateral direction and a first insulative member retaining the first contacts, the second contacting module unit having plural second contacts arranged along the lateral direction and a second insulative member retaining the second contacts, wherein each of the first and second insulative members includes a same engagement structure, through which the first insulative member and the second insulative member are assembled into a whole by interference arrangement and then inserted into the insulative housing together.

A wafer connector is disclosed in which a plurality of twin-axial wires are terminated to the tails of ground and signal terminals of the connector. Each twin-axial wire includes a pair of signal wires enclosed in a conductive sheath. A conductive grounding clamp is provided that contacts the sheaths of the twin-axial wires and holds them together as a unit to facilitate the attachment of the wires to the connector terminal tails. The clamp has two opposing halves that cooperatively define openings which receive the twin-axial wires and flat, interconnecting portions extending between the openings that provide contact points where the grounding clamp may be attached to the connector terminal tails.

Techniques and mechanisms for providing a reference potential with a flexible circuit device. In an embodiment, the flexible circuit device includes a first interconnect to exchange a signal and a second interconnect to exchange a reference potential that facilitates shielding of the signal. The first and second interconnects are variously coupled to a printed circuit board (PCB) via a first contact and a second contact of a hardware interface. During such coupling, a maximum height of the second interconnect from a side of the PCB at the hardware interface is greater than a maximum height of the first interconnect from the side of the PCB at the hardware interface. In another embodiment, a distance of the first contact from an end of the flexible circuit device is different than a distance of the second contact from the end of the flexible circuit device.

A contact ribbon configured to connect a cable to a substrate includes a plurality of signal contacts, a ground plane, and at least one ground contact extending from the ground plane. The plurality of signal contacts are connected by a support member, and the support member is removable after the plurality of signal contacts are connected to the cable.

The invention relates to a connector for a shielded electric cable (1), said shielded electric cable (3) comprising at least one conductor and a shielding (5) that at least partially covers said shielded electric cable (3), said connector (1) comprising a connector housing (7) containing the conductor, the invention being characterized in that said shielding (5) is partially arranged around said connector housing (7), said connector housing (7) being electroconductive, and said connector (1) comprising a holding ferule (11) arranged around the shielding (5) in such a way as to maintain the connection of the shielding (5) to the connector housing (7) both mechanically by means of clamping and also by direct electrical connection. The invention also relates to a method for the assembly of such a connector for a shielded electric cable.

A composite connector, including: a first insulating body and a second insulating body, respectively having a first tongue plate and a second tongue plate arranged at the front ends thereof; multiple terminals respectively fixed on the first and second insulating bodies and exposed from surfaces of the first and second tongue plates; a first shielding sheet and a second shielding sheet which are integrally formed, fixed in the first and second tongue plates respectively and are positioned on one side of the terminals; and a metal shell forming a first insertion opening and a second insertion opening around the first and second tongue plates respectively. The first insertion opening is configured for insertion of a first docking connector. The second insertion opening is configured for insertion of a second docking connector. A combination of the first and second insertion openings are configured for insertion of a third docking connector.

A connector shield for a flat flexible cable comprises a housing defining a connector space on a first end thereof for receiving a signal cable connector, and a cable space on a second end thereof for at least partially receiving an end of the flat flexible cable. The cable space defines a width greater than that of the connector space and a height less than that of the connector space. A plurality of contact elements extend from the housing and into the cable space for electrically contacting a conductive element of the flat flexible cable.