An electrical plug-in connector for differential signal transmission, having an external conductor contact element, a dielectric and at least one internal conductor contact element pair for differential signal transmission. The dielectric extends along a longitudinal axis through the external conductor contact element. The internal conductor contact element pair has a first internal conductor contact element and a second internal conductor contact element which extend along the longitudinal axis through the dielectric. The external conductor contact element and/or the dielectric have a compensation geometry in order to compensate for an asymmetry of the internal conductor contact element pair with respect to the longitudinal axis. As an alternative or in addition, it is provided that the internal conductor contact element pair has a compensation geometry in order to compensate for an asymmetry of the external conductor contact element and/or of the dielectric with respect to the longitudinal axis.

A coupler couples a first connector with a second connector wherein each of the connectors is coupled to exactly two electrical conductors. Each coupler can be utilized in a shielded (e.g., metal) or non-shielded (e.g. non-metal) form as appropriate to a specific application. Each coupler includes exactly one pair of pin contacts, preferably with a square or rectangular cross- section. Each end of the pin contacts includes four tapered faces that join at a flattened apex and are configured to be received by the tuning fork contact of the connector. The pair of pin contacts are offset from one another and cross one another within the coupler to maintain electrical polarity as electricity travels from the tuning fork contacts of a first connector to the pin contacts of the coupler and onward to the tuning fork contacts of a second connector.

A female connector module to be connected to a male terminal module is provided with a tubular female shield member, a tubular housing arranged on an outer periphery of the female shield member, a front mask provided on a tip portion of the housing, and an electrically conductive rubber for conduction between a male shield member of the male terminal module and the female shield member. The front mask has an end wall for facing an end surface of the housing and a side wall for covering an outer peripheral surface of the tip portion. The end wall has a through hole into which the male terminal module being inserted. The electrically conductive rubber is so arranged inside the through hole as to contact an end surface of the female shield member while being held in contact with an outer peripheral surface of the male shield member.

Assembly comprising a cable having at least two signal wires, and a connector connected to the shielded cable, wherein the connector comprises at least two elongated inner signal contacts each connected to a wire of the cable, wherein the connector comprises a shielding portion formed of an inner shield and an outer shield, and wherein the inner shield at least approximately completely surrounds the wires of the cable and the outer shield at least partially surrounds the inner shield.

A standard for near end crosstalk of a category 6A cable, including a registered jack 45 (RJ45), a clamp connected to the RJ45, a first attenuator and a second attenuator. The RJ45 includes a first signal twisted pair to transmit a first source signal and a second source signal, and a second signal twisted pair to transmit a third source signal and a fourth source signal. The clamp includes a first signal pair connector electrically connected to the first signal twisted pair, a second signal pair connector electrically connected to the second signal twisted pair, a first differential amplification circuit and a second differential amplification circuit. The first attenuator is electrically connected to the first signal pair connector. The second attenuator is electrically connected to the second signal pair connector. The second attenuator and the first attenuator are configured to detect the near end crosstalk.

A plug connector having a housing and at least four contact elements arranged within the housing to transmit high-frequency signals, wherein two contact elements respectively form a contact element pair, each of which is integrated into an insulating body. In that arrangement, the insulating bodies are each surrounded by a shield.

A plug connector having a contact support (2), wherein at least one contact chamber is provided in the contact support (2) and a contact partner (3) is inserted into the contact chamber and primarily locked therein, wherein each contact partner is allocated a throughgoing hole on one side of the contact support (2) for the primary latch formation and so as to increase the transmission rate, and a further single throughgoing hole is provided on the opposite side of the contact support (2), wherein the throughgoing holes have an elongated rectangular shape.

A cable assembly includes coaxially arranged inner and outer barrels. The outer barrel overlaps a portion of the inner barrel. The cable assembly further includes a cable that has at least one wire surrounded by an inner insulator that is covered in a metallic shield. The metallic shield is arranged in between the inner and outer barrels. The inner barrel includes a retention feature that is arranged beneath the metallic shield. The retention feature protrudes radially outward from the inner barrel to an outermost diameter. The outer barrel includes a crimped portion that is arranged adjacent to the retention feature and has an innermost diameter that is less than the outermost diameter to capture the metallic shield therebetween and prevent the outer barrel from axial movement relative to the inner barrel.

A cable assembly includes coaxially arranged inner and outer barrels. The outer barrel overlaps a portion of the inner barrel. The inner and outer barrels respectively include first and second features that cooperate with one another to form a retention feature. The cable assembly has a cable that has at least one wire surrounded by an inner insulator that is covered in a metallic shield. The metallic shield is arranged in between the inner and outer barrels. The first feature is arranged beneath the metallic shield, and the second feature is arranged over the metallic shield. At least one of the first and second features extends in a radial direction relative to the other of the first and second features to capture the metallic shield with the retention feature.

Miniaturized electrical connector systems are disclosed herein. In exemplary aspects disclosed herein, the connector system includes a twinaxial female connector having a housing and at least one dielectric positioned therein. The at least one dielectric defines two parallel channels configured to receive at least a portion of two conductors of a twinaxial cable. The twinaxial female connector includes an oval interface configured to orient and align the conductors of the twinaxial cable with mating pins of a male connector. The twinaxial female connector further includes two spring-type interconnects positioned within the oval interface, each configured to directly contact a conductor of the twinaxial cable and a mating pin of the male connector. The twinaxial female connector further includes a retaining clip attached to an exterior of the housing with a lever arm biased towards and pivotable from an engaged orientation. Such features reduce the manufacturing complexity, cost, and overall size.