A contact assembly comprises a first pair of contact elements connected to a first pair of signal lines in a first connector, a second pair of contact elements connected to a second pair of signal lines in a second connector, and a first electrical arrangement connecting a first contact element of the first pair of contact elements and the first contact element of the second pair of contact elements. A second contact element of the first pair of contact elements and a first contact element of the second pair of contact elements are positioned adjacent one another. A capacitance of the first electrical arrangement corresponds to a capacitance between the second contact element of the first pair of contact elements and the first contact element of the second pair of contact elements.

A signal terminal set includes a first material strip including a first connecting plate and a plurality of first signal terminals connected in parallel to the first connection plate and providing a respective bridging segment, and a second material strip including a second connecting plate attached onto the first connection plate and a plurality of second signal terminals connected in parallel to the second connection plate and providing a respective travel segment to create with the bridging segments of the first signal terminals a compensated structure, simplifying the manufacturing process and increasing the yield.

A signal terminal set includes a first material strip including a first connecting plate and a plurality of first signal terminals connected in parallel to the first connection plate and providing a respective bridging segment, and a second material strip including a second connecting plate attached onto the first connection plate and a plurality of second signal terminals connected in parallel to the second connection plate and providing a respective travel segment to create with the bridging segments of the first signal terminals a compensated structure, simplifying the manufacturing process and increasing the yield.

A wafer assembly for an electrical connector that has a first and second wafers configured to interlock with one another. Each of the wafers has at least one contact that has a body portion with a mating end for coupling to a mating contact and a tail end opposite the mating end for engaging a printed circuit board and an overmold covering the body portion such that the mating and tail ends extend from opposite sides of the overmold. A conductive elongated spring member is sandwiched between the first and second wafers. The wafer assembly can include one or more filter components.

A wafer assembly for an electrical connector that has a first and second wafers configured to interlock with one another. Each of the wafers has at least one contact that has a body portion with a mating end for coupling to a mating contact and a tail end opposite the mating end for engaging a printed circuit board and an overmold covering the body portion such that the mating and tail ends extend from opposite sides of the overmold. A conductive elongated spring member is sandwiched between the first and second wafers. The wafer assembly can include one or more filter components.

Electrical connector including a plurality of mating conductors. Each of the mating conductors extends between an engagement portion and an interior portion. The engagement portions of the mating conductors are configured to engage contacts of the mating connector. The engagement portions are located proximate to one another at a first nodal region. The interior portions are located proximate to one another at a second nodal region. The electrical connector also includes a first open-ended conductor electrically connected to the engagement portion of a first mating conductor of the plurality of mating conductors and extending from the first nodal region. The electrical connector also includes a second open-ended conductor electrically connected to the interior portion of a second mating conductor of the plurality of mating conductors and extending from the second nodal region. The first open-ended conductor is capacitively coupled to the second open-ended conductor.

Electrical connector including a plurality of mating conductors. Each of the mating conductors extends between an engagement portion and an interior portion. The engagement portions of the mating conductors are configured to engage contacts of the mating connector. The engagement portions are located proximate to one another at a first nodal region. The interior portions are located proximate to one another at a second nodal region. The electrical connector also includes a first open-ended conductor electrically connected to the engagement portion of a first mating conductor of the plurality of mating conductors and extending from the first nodal region. The electrical connector also includes a second open-ended conductor electrically connected to the interior portion of a second mating conductor of the plurality of mating conductors and extending from the second nodal region. The first open-ended conductor is capacitively coupled to the second open-ended conductor.

An electrical connector for transmitting data signals between the insulated conductors of a first data cable and corresponding insulated conductors of a second data cable, including a first part having a socket shaped to at least partially receive a plug of said first data cable; a second part having a plurality of insulation displacement contact slots shaped to receive end sections of the conductors of the second data cable; and a plurality of electrically conductive contacts including resiliently compressible spring finger contacts extending into the socket for electrical connection with corresponding conductors of the first cable; insulation displacement contacts seated in corresponding insulation displacement contact slots for effecting electrical connection with corresponding conductors of the second data cable; and mid sections extending therebetween, wherein relative movement between the mid sections of the contacts is inhibited by a fastener.

An electrical connector for transmitting data signals between the insulated conductors of a first data cable and corresponding insulated conductors of a second data cable, including a first part having a socket shaped to at least partially receive a plug of said first data cable; a second part having a plurality of insulation displacement contact slots shaped to receive end sections of the conductors of the second data cable; and a plurality of electrically conductive contacts including resiliently compressible spring finger contacts extending into the socket for electrical connection with corresponding conductors of the first cable; insulation displacement contacts seated in corresponding insulation displacement contact slots for effecting electrical connection with corresponding conductors of the second data cable; and mid sections extending therebetween, wherein relative movement between the mid sections of the contacts is inhibited by a fastener.

A plug-in connector that can be manufactured using MID technology, which nevertheless ensures good crosstalk compensation and thus a high data transmission rate has two assembled contact carrier parts with contacts are disposed between these contact carrier parts. A separate, electrically conductive compensation coating may be provided in each contact carrier part, each having a connection surface for producing an electrically conductive connection to an associated contact. Each of the electrically conductive compensation coatings has at least one coupling surface for a targeted capacitive coupling with one or more further contacts. Between each coupling surface and the associated contact, an insulating film or part of an insulating film is provided, which acts as a dielectric and a spacer. By selection of the contacts to be coupled and the capacitance of the coupling, good compensation of undesired crosstalk can thus be achieved in a simple manner.