A connector comprises a housing and a plurality of contacts retained in the housing. Each of the contacts extends in a longitudinal direction and has a retained portion, a contacting portion disposed in front of the retained portion in the longitudinal direction, and a connecting portion disposed behind the retained portion in the longitudinal direction. Each of the contacting portion and the connecting portion are shifted with respect to the retained portion in a vertical direction perpendicular to the longitudinal direction. The housing is in contact with the retained portion of each of the contacts from both above and below in the vertical direction and from both right and left in a lateral direction perpendicular to the vertical direction and the longitudinal direction.

This invention relates to a covered wire coupling type information communication network, an electromagnetic field coupling communication method and an electromagnetic field coupler, which makes it possible to solve the problem with the mechanical contact system and the structure where wires are exposed in a connector. A first covered wire and a second covered wire are placed in close proximity to each other in a coupling unit, and electromagnetic coupling in the coupling unit creates a data connection between the first and second covered wire.

A connector assembly allows a conductive terminal to provide shielding to reduce any effect of external interference on signal transmission of the connector assembly so as to meet signal transmission requirements for the connector assembly, and with the use of a jumper conductor, at least partial conductive terminals on the connector assembly can be electrically interconnected with no need of any additional jumper, such that an electronic device using such connector assembly can be made compact in size desirably.

A connector assembly is provided. The connector assembly allows a conductive terminal to provide shielding to reduce any effect of external interference on signal transmission of the connector assembly so as to meet signal transmission requirements for the connector assembly, and with the use of a jumper conductor, at least partial conductive terminals on the connector assembly can be electrically interconnected with no need of any additional jumper, such that an electronic device using such connector assembly can be made compact in size desirably.

[Problem] To provide an electrical connector capable of adequately ensuring a stable state of electrical communication between ground members.

[Means of Solution] The retaining member, which retains rows of signal transmission paths consisting of multiple signal transmission paths arranged side by side in a direction along the major faces of the retaining member together with a first and a second ground member, has perforation portions extending in the through-thickness direction of the retaining member at locations between adjacent signal transmission paths; the electrical connector has provided therein a shorting member of electrically conductive plastics co-molded with the first ground member and second ground member; and the shorting member has first base portions that are located at the first ground member side and are in contact with the first ground member, second base portions that are located at the second ground member side and are in contact with the second ground member, and coupling portions that are located within the perforation portions and couple the first base portions and the second base portions.

A controlled-impedance cable assembly for removably attaching a controlled-impedance cable to a surface of a device. Signal contacts are attached to signal conductors of cables and ground members are coupled to shields of the cables. Ends of the signal conductors and of elongated appendages extending from the ground members are positioned to make a pressure contact to pads and ground lands on the surface. Pressure to make those contacts may come from deflection of the ends of the signal conductors and elongated ground appendages or from a spring. The signal contacts and elongated appendages may be positioned to provide an impedance matching an impedance with the cables.

A controlled-impedance cable assembly for removably attaching a controlled-impedance cable to a surface of a device. Signal contacts are attached to signal conductors of cables and ground members are coupled to shields of the cables. Ends of the signal conductors and of elongated appendages extending from the ground members are positioned to make a pressure contact to pads and ground lands on the surface. Pressure to make those contacts may come from deflection of the ends of the signal conductors and elongated ground appendages or from a spring. The signal contacts and elongated appendages may be positioned to provide an impedance matching an impedance with the cables.

A plug-in contact device for preventing or extinguishing an arc when separating or closing a direct current connection includes: at least one plug-in connector each having a main contact, HA, and an auxiliary contact, HI, the HA including a first contact half, HA1, and a second contact half, HA2, which are releasably plugged together. The HA: electrically conductively connects the HA1 and the HA2 in a plugged-together state of the respective plug-in connector, galvanically separates the HA1 and the HA2 in a released state of the respective plug-in connector, electrically conductively connects the HA1 and the HA2 in a first intermediate state of the respective plug-in connector between the plugged-together state and the released state, and galvanically separates the HA1 and the HA2 in a second intermediate state of the respective plug-in connector between the first intermediate state and the released state.

A plug-in contact device for preventing or extinguishing an arc when separating or closing a direct current connection includes: at least one plug-in connector each having a main contact, HA, and an auxiliary contact, HI, the HA including a first contact half, HA1, and a second contact half, HA2, which are releasably plugged together. The HA: electrically conductively connects the HA1 and the HA2 in a plugged-together state of the respective plug-in connector, galvanically separates the HA1 and the HA2 in a released state of the respective plug-in connector, electrically conductively connects the HA1 and the HA2 in a first intermediate state of the respective plug-in connector between the plugged-together state and the released state, and galvanically separates the HA1 and the HA2 in a second intermediate state of the respective plug-in connector between the first intermediate state and the released state.

An electrical connector includes a housing, a signal contact, and a ground shield. The housing includes a base having a front side and an opposite rear side. The signal contact is received in the base and has a mating segment that extends forward of the front side. The ground shield is received in the base and extends forward of the front side. The ground shield surrounds the signal contact on at least one side thereof. The ground shield includes a deflectable spring tab extending from an inner surface of the ground shield towards the signal contact without engaging the signal contact. The spring tab is positioned forward of the front side of the base. The spring tab is configured to be deflected outward by a mating connector in a direction away from the signal contact during a mating operation.