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.

The invention relates to an electrical connector assembly, comprising an electrical connector and a cable connected to the electrical connector, which each have at least one conductor pair for transferring a differential signal, wherein the cable has a first section and the electrical connector has a second section, in which second section the conductor pair has plug contacts, and wherein the conductors have a first mutual distance (X) in the first section and a second mutual distance (Y) in the second section, which second mutual distance is greater than the first distance, wherein an intermediate section, in which the distance of the conductors of a conductor pair increases toward a plugging end of the electrical connector, is formed between the first section and the second section, wherein the conductor pair is surrounded by a conductor pair shield in the first section and/or in the second section, which conductor pair shield shields the conductor pair from external electromagnetic influences, and wherein the conductors are surrounded by a conductor shield in at least part of the intermediate section, which conductor shield shields the conductors from external electromagnetic influences and from electromagnetic influences of the other conductor. The invention further relates to a method for signal transfer.

A shield connector is mounted on a terminal of a shield cable including a conductor core wire and a shield body surrounding the conductor core wire. The shield connector includes a conductive inner terminal connected to the conductor core wire, a conductive cylindrical outer terminal connected to the shield body, and an inner housing holding the inner terminal in a hollow part of the outer terminal. A projection part is formed on an outer surface of the inner housing to maintain a distance between an outer surface of the inner terminal and an inner surface of the outer terminal at a predetermined inter-terminal distance from a tip side of the shield connector to a base end side thereof.

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 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.

Methods and systems for providing crosstalk compensation in a jack are disclosed. According to one method, the crosstalk compensation is adapted to compensate for undesired crosstalk generated at a capacitive coupling located at a plug inserted within the jack. The method includes positioning a first capacitive coupling a first time delay away from the capacitive coupling of the plug, the first capacitive coupling having a greater magnitude and an opposite polarity as compared to the capacitive coupling of the plug. The method also includes positioning a second capacitive coupling at a second time delay from the first capacitive coupling, the second time delay corresponding to an average time delay that optimizes near end crosstalk. The second capacitive coupling has generally the same overall magnitude but an opposite polarity as compared to the first capacitive coupling, and includes two capacitive elements spaced at different time delays from the first capacitive coupling.

Methods and systems for providing crosstalk compensation in a jack are disclosed. According to one method, the crosstalk compensation is adapted to compensate for undesired crosstalk generated at a capacitive coupling located at a plug inserted within the jack. The method includes positioning a first capacitive coupling a first time delay away from the capacitive coupling of the plug, the first capacitive coupling having a greater magnitude and an opposite polarity as compared to the capacitive coupling of the plug. The method also includes positioning a second capacitive coupling at a second time delay from the first capacitive coupling, the second time delay corresponding to an average time delay that optimizes near end crosstalk. The second capacitive coupling has generally the same overall magnitude but an opposite polarity as compared to the first capacitive coupling, and includes two capacitive elements spaced at different time delays from the first capacitive coupling.

A connector having a floating structure and a reduced profile that improves transmission characteristics of a signal transmission is provided. A connector 10 according to the present disclosure is to be fitted to a connection object 60 and includes a first insulator 20, a second insulator 30 that is movable relative to the first insulator 20, a contact 60 attached to the first insulator 20 and the second insulator 30, and adjustment members 50a and 50b having electrical conductivity arranged within the first insulator 20. The adjustment members 50a and 50b include adjustment portions 51a and 51b, respectively, which are configured to oppose the contact 60.

An electric connector comprises a contact, a base assembly, a pair of first circuit board sections, and a plurality of electric components. The base assembly has a connector face on a first side and an interior side opposite to the connector face. The contact is disposed on the connector face. The pair of first circuit board sections are disposed on the interior side and extend away from the base assembly. The pair of first circuit board sections face each other. At least one electric component is disposed on each of the first circuit board sections.

Various techniques are described to terminate a differential wire pair using combinations of CMCs, transformers, autotransformers, differential mode chokes (DMCs), and AC-coupling capacitors. The techniques improve the AC common mode insertion loss without attenuating the differential data signals, while easing the requirements of the CMC. In one example, an autotransformer, having a first winding, a second winding, and a center tap, is connected across a PHY, where the center tap provides a low impedance to ground for attenuating common mode noise. A CMC is coupled across the autotransformer and a pair of wires carrying differential data, where the CMC greatly attenuates common mode noise. The requirements of the CMC are reduced due to the autotransformer.