A data connector adapter includes a plug body having first and second plug connection ends, an electrically conductive plug shield and a contact carrier. The first and second plug connection ends respectively have first and second plug contact connection patterns for connecting first and second data connectors. The contact carrier is arranged between the plug connection ends and carries two first contacts and two second contacts respectively forming the first and second plug contact connection patterns. One of the first contacts in each case is electrically conductively connected to one of the second contacts via a contact connection section. The first and second contacts are surrounded at least in sections respectively by electrically insulating first and second carrier bodies having first and second dielectric constants ε.sub.R1, ε.sub.R2. Outer circumferential surfaces of the carrier bodies bear against an inner wall surface of the plug shield at least in sections.

A data connector adapter includes a plug body having first and second plug connection ends, an electrically conductive plug shield and a contact carrier. The first and second plug connection ends respectively have first and second plug contact connection patterns for connecting first and second data connectors. The contact carrier is arranged between the plug connection ends and carries two first contacts and two second contacts respectively forming the first and second plug contact connection patterns. One of the first contacts in each case is electrically conductively connected to one of the second contacts via a contact connection section. The first and second contacts are surrounded at least in sections respectively by electrically insulating first and second carrier bodies having first and second dielectric constants ε.sub.R1, ε.sub.R2. Outer circumferential surfaces of the carrier bodies bear against an inner wall surface of the plug shield at least in sections.

A connection module includes a first assembly and a second assembly. The first assembly has a rest portion for resting thereon an exposed portion of a covered electrical wire for differential signal transmission. A cable accommodates the covered electrical wire in a jacket. The exposed portion is not covered with the jacket, exposing a covering of the covered electrical wire. The second assembly has a presser portion pressing the exposed portion rested on the rest portion against the rest portion. A position of the exposed portion is determined by combining the first assembly with the second assembly.

A shielding electrical terminal is presented herein. The shielding electrical terminal includes a securing portion that is configured to attach to an outer shield conductor of a shielded cable and a cylindrical mating portion having an inner surface configured to make electrical contact with a corresponding cylindrical shield terminal inserted within the mating portion. The inner surface of the mating portion defines a plurality of protrusions that extend from the inner surface.

A wide bandwidth signal connector plug, comprising a plurality of signal pins having a first anchor portion and a first mating portion, and a plurality of ground pins having a second anchor portion and a second mating portion. The plurality of ground pins is adjacent to the plurality of signal pins. The plurality of signal pins has a first thickness and the plurality of ground pins has a second thickness that is greater than the first thickness. The first anchor portion has a first width and the second anchor portion has a second width that is greater than the first width.

A cable termination that provides low signal distortion even at high frequencies. Conductive elements of the cable are fused to edges of signal conductors in a cable connector or other component terminating the cable. For terminating a differential pair, the conductive elements of the cable may be terminated to opposing edges of a pair of signal conductors in the cable termination. The conductive elements may be shaped such that the spacing between signal paths passing through the conductive elements of the cable and into the signal conductors of the cable termination is uniform.

A backplane connector includes a housing and a number of wafers assembled to the housing. Each wafer includes a number of conductive terminals, an insulating frame and a metal shield. The housing includes an insulating housing and a metal shell fixed to the insulating housing. The insulating housing includes a number of slots for positioning the wafers. The metal shell is provided with a mating surface and a number of terminal receiving grooves. The contact portions of the conductive terminals are exposed in the corresponding terminal receiving grooves. The present disclosure improves the structural strength of the backplane connector and reduces the risk of damage the mating surface due to the push or collision of a mating connector.

A coaxial terminator for terminating a coaxial equipment port includes a female connector, an outer housing, at least one support element, a center conductor, cured resin dielectric, and one or more resistive elements. The female connector is disposed within the outer housing, is supported within the outer housing by the at least one support element, and is configured to receive a male pin of the coaxial equipment port. The center conductor has a proximal portion and a distal portion and is coaxially coupled to the female connector at the proximal portion and encircled by cured resin dielectric at the distal portion. The cured resin dielectric is cured in place between the center conductor and the outer housing. The one or more resistive elements are in electrical communication at a first end with the center conductor and at a second end with the inner housing.

A connector assembly includes a male connector and a female connector. The male connector includes N pins with different lengths, and the N pins respectively correspond to N different transmission signals. The female connector includes N signal layers configured to transmit the N different transmission respectively, and each of the N signal layers includes N pass gates. One of the N pass gates of each of the N signal layers is configured to be coupled to a corresponding one of the N pins.

A connector assembly includes a male connector and a female connector. The male connector includes N pins with different lengths, and the N pins respectively correspond to N different transmission signals. The female connector includes N signal layers configured to transmit the N different transmission respectively, and each of the N signal layers includes N pass gates. One of the N pass gates of each of the N signal layers is configured to be coupled to a corresponding one of the N pins.