Communications jacks include at least first through third jackwire contacts and a flexible substrate that has a first finger and a second finger. The first jackwire contact and the third jackwire contact are each mounted on the first finger and the second jackwire contact is mounted on the second finger.

A system that reduces crosstalk and return loss within electrical communication connectors includes at least two compensating capacitors connected in series that compensate each offending capacitor. An additional inductive component that is connected between two compensating capacitors so that the adjustable inductance of the inductive component can be varied to modify the capacitive coupling effect achieved by the compensating capacitors as a function of frequency. A shape-neutral structure containing two compensating capacitors and one series inductive component in between is positioned so that each compensating capacitor is juxtaposed parallel to the offending capacitor. There is no direct contact between the shape-neutral structure and the transmission lines, and the shape-neutral structure does not change the shape of PCB traces and reduces both crosstalk and return loss.

A system that reduces crosstalk and return loss within electrical communication connectors includes at least two compensating capacitors connected in series that compensate each offending capacitor. An additional inductive component that is connected between two compensating capacitors so that the adjustable inductance of the inductive component can be varied to modify the capacitive coupling effect achieved by the compensating capacitors as a function of frequency. A shape-neutral structure containing two compensating capacitors and one series inductive component in between is positioned so that each compensating capacitor is juxtaposed parallel to the offending capacitor. There is no direct contact between the shape-neutral structure and the transmission lines, and the shape-neutral structure does not change the shape of PCB traces and reduces both crosstalk and return loss.

A modular plug for terminating a telecommunications cable includes a housing, a plurality of wire contacts, and a wire manager fitted in an internal cavity of the housing. The wire manager includes internal walls shaping a central channel, opposing edges on the internal walls defining a gate in the central channel, and tabs projecting from the gate in the central channel. The tabs define an upper portion and a lower portion in the gate. A strain relief member attaches to the wire manager in an intermediate position to partially restrain the telecommunications cable relative to the wire manager, and is restrained by the housing in a final position to completely restrain the telecommunications cable relative to the wire manager.

A printed circuit board includes a plurality of layers including attachment layers and routing layers; and columns of via patterns formed in the plurality of layers, wherein via patterns in adjacent columns are offset in a direction of the columns, each of the via patterns comprising: first and second signal vias forming a differential signal pair, the first and second signal vias extending through at least the attachment layers; and at least one conductive shadow via located between the first and second signal vias of the differential pair. In some embodiments, at least one conductive shadow via is electrically connected to a conductive surface film.

A signal transmission cable of the present invention comprises a terminal part electrically connectable to an external device, and a cable including metal wires of eight or more channels that are electrically connectable to the terminal part, the terminal part has a substrate including a plurality of connection parts that are electrically connectable to the external device and connected respectively to the metal wires of the individual channels included in the cable, and the metal wires of the mutually different channels that are adjacently connected at the plurality of connection parts are arranged so as not to be adjacent to each other inside the cable.

A signal transmission cable of the present invention comprises a terminal part electrically connectable to an external device, and a cable including metal wires of eight or more channels that are electrically connectable to the terminal part, the terminal part has a substrate including a plurality of connection parts that are electrically connectable to the external device and connected respectively to the metal wires of the individual channels included in the cable, and the metal wires of the mutually different channels that are adjacently connected at the plurality of connection parts are arranged so as not to be adjacent to each other inside the cable.

An apparatus and method for crosstalk compensation in a jack of a modular communications connector includes a flexible printed circuit board connected to jack contacts and to connections to a network cable. The flexible printed circuit board includes conductive traces arranged as one or more couplings to provide crosstalk compensation.

An apparatus and method for crosstalk compensation in a jack of a modular communications connector includes a flexible printed circuit board connected to jack contacts and to connections to a network cable. The flexible printed circuit board includes conductive traces arranged as one or more couplings to provide crosstalk compensation.

Communications jacks include a housing having a plug aperture that is configured to receive a mating RJ-45 plug along a longitudinal axis and eight jackwire contacts that are arranged as four differential pairs of jackwire contacts, each of the jackwire contacts including a plug contact region that extends into the plug aperture. A first of the jackwire contacts is configured to engage a longitudinally extending surface of a first blade of a mating RJ-45 plug when the mating RJ-45 plug is fully received within the plug aperture.