Embodiments of the present invention relate to the field of telecommunication, and more specifically, to communication connectors such as, for example, shielded plug and jack connectors. In an embodiment, the present invention is a communication jack that includes a housing and a front sled assembly having a plurality of plug interface contacts (PICs), the front sled assembly being moveable along a horizontal plane of the communication jack between a first position and a second position, the first position being different from the second position.

An inline communications connector is provided that includes a housing and tip and ring contacts that are mounted in the housing. The tip contact includes an input tip socket, an output tip socket and a tip socket connection section that physically and electrically connects the input and output tip sockets. The ring contact includes an input ring socket, an output ring socket and a ring socket connection section that physically and electrically connects the input and output ring sockets. The input tip socket is not collinear with the output tip socket and the input ring socket is not collinear with the output ring socket.

Embodiments of the present invention relate to designs for network jacks which can be used for cable connectivity. In an embodiment, the present invention is an RJ45 jack that utilizes a thin dielectric film between two layers of PICs that provide crosstalk compensation by way of their geometry. Compensation is achieved by way of capacitor plates which sandwich a thin dielectric film. This allows for the layers of PICs to be in close proximity and achieve higher coupling where desired, allowing a greater amount of compensation to occur close to the plug/jack contact point. This can have the effect of moving compensation closer to the plug/jack contact point, which in turn may reduce the amount of compensation needed further along the data path.

Embodiments of the present invention relate to designs for network jacks which can be used for cable connectivity. In an embodiment, the present invention is an RJ45 jack that utilizes a thin dielectric film between two layers of PICs that provide crosstalk compensation by way of their geometry. Compensation is achieved by way of capacitor plates which sandwich a thin dielectric film. This allows for the layers of PICs to be in close proximity and achieve higher coupling where desired, allowing a greater amount of compensation to occur close to the plug/jack contact point. This can have the effect of moving compensation closer to the plug/jack contact point, which in turn may reduce the amount of compensation needed further along the data path.

A modular jack connector compensates for plug characteristics via a controlled primary compensation in the immediate vicinity of the connector interface. A jack contact assembly is positioned within a jack housing and includes first and second sets of elongate contacts each having a plug contact portion and a signal output portion. Each elongate contact is configured such that their respective plug contact portions are coplanar and a signal path is defined between their plug contact portions and their signal output portions. A flexible circuit board is coupled proximate to the plug contact portions, and configured to provide capacitance compensation between respective contacts engaged thereby, wherein the capacitance compensation is offset from a signal path defined between the plug contact portions and the corresponding signal output portions.

A modular jack connector compensates for plug characteristics via a controlled primary compensation in the immediate vicinity of the connector interface. A jack contact assembly is positioned within a jack housing and includes first and second sets of elongate contacts each having a plug contact portion and a signal output portion. Each elongate contact is configured such that their respective plug contact portions are coplanar and a signal path is defined between their plug contact portions and their signal output portions. A flexible circuit board is coupled proximate to the plug contact portions, and configured to provide capacitance compensation between respective contacts engaged thereby, wherein the capacitance compensation is offset from a signal path defined between the plug contact portions and the corresponding signal output portions.

A circuit board and an electrical connector with the same are disclosed in the present invention. The circuit board includes a first line layer, a first insulating layer, a second line layer, an insulating substrate, a third line layer, a second insulating layer and a fourth line layer, which are stacked from top to bottom. A first metal line and a second metal line are formed on the first line layer and the second line layer, respectively, and together constitute a first differential line pair. A third metal line and a fourth metal line are formed on the third line layer and the fourth line layer, respectively, and together constitute a second differential line pair. Two metal lines constituting each differential line pair are arranged up and down and have different widths, thereby reducing signal crosstalk between adjacent differential line pairs.

A substrate connector includes an insulative housing fixed onto a substrate, a first terminal electrically connected to a first communication line of a communication cable in the inside of the housing and electrically connected to a circuit of the substrate on the outside of the housing, and a second terminal electrically connected to a second communication line of the communication cable in the inside of the housing and electrically connected to the circuit of the substrate on the outside of the housing. The housing includes a main body that is fixed onto the substrate, a terminal-retaining portion arranged in the inside of the main body, integrally formed with the housing, and retains the first and second terminals, and a shell-retaining portion including slit portions formed between the main body and the terminal-retaining portion and to which a shield shell surrounding the first and second terminals is inserted.

A twisted pair communications device and associated twisted pair communications system are disclosed. One twisted pair communications device includes a plurality of twisted pair connectors each associated with a different twisted pair communication channel, and a multi-channel connector communicatively connected to each of the plurality of twisted pair connectors. The multi-channel connector is configured to transmit and receive communication signals associated with each of the twisted pair communication channels on a multi-channel twisted pair cable and includes a plurality of wire pairs disposed in a plurality of rows within the connector. Fewer than all of the plurality of wire pairs are communicatively connected to twisted pair connectors, and wherein unassociated wire pairs in the multi-channel connector separate at least two groups of wire pairs associated with different twisted pair communication channels.

A twisted pair communications device and associated twisted pair communications system are disclosed. One twisted pair communications device includes a plurality of twisted pair connectors each associated with a different twisted pair communication channel, and a multi-channel connector communicatively connected to each of the plurality of twisted pair connectors. The multi-channel connector is configured to transmit and receive communication signals associated with each of the twisted pair communication channels on a multi-channel twisted pair cable and includes a plurality of wire pairs disposed in a plurality of rows within the connector. Fewer than all of the plurality of wire pairs are communicatively connected to twisted pair connectors, and wherein unassociated wire pairs in the multi-channel connector separate at least two groups of wire pairs associated with different twisted pair communication channels.