A Peripheral Component Interconnect Express/Serial Attached SCSI (PSAS) female connector includes a frame member, a terminal member, and a cover member; the frame member including a terminal groove disposed in the frame member and a tilt portion disposed in the terminal groove adjacent to a plug end; the terminal member inserted in the frame member and including a Serial Advanced Technology Attachment (SATA) 7 pin terminal, a Serial Attached SCSI (SAS) 40 pin terminal, a 15 Pin signal terminal, a 6 Pin terminal, and a 4 Pin terminal. When the PSAS female connector is engaged with the male connector, the SATA 7 Pin terminal and the SAS 40 Pin terminal are pressed by a terminal of the male connector to be bent toward an outer lateral side of the terminal groove to contact the elastic plate of the cover member. The present invention effectively improves the cross interference during high speed transmission, thereby achieving the Generation 5 performance requirement.

A contact module includes a frame assembly having a leadframe and a dielectric frame partially encasing the leadframe. The leadframe includes ground conductors each having a transition portion extending between a mating end configured to be mated to a mating connector and a terminating end configured to be terminated to one of a circuit board or a cable conductor. The dielectric frame includes dielectric material encasing at least a portion of each transition portion. Each mating end extends from the dielectric frame for connection with the mating connector. Each terminating end extends from the dielectric frame for connection with the circuit board or the cable conductor. The contact module includes resistive elements within the dielectric frame. Each resistive element is coupled in series with the transition portion of the corresponding ground conductor.

A Peripheral Component Interconnect Express/Serial Attached SCSI (PSAS) female connector includes a frame member, a terminal member, and a cover member; the frame member including a terminal groove disposed in the frame member and a tilt portion disposed in the terminal groove adjacent to a plug end; the terminal member inserted in the frame member and including a Serial Advanced Technology Attachment (SATA) 7 pin terminal, a Serial Attached SCSI (SAS) 40 pin terminal, a 15 Pin signal terminal, a 6 Pin terminal, and a 4 Pin terminal. When the PSAS female connector is engaged with the male connector, the SATA 7 Pin terminal and the SAS 40 Pin terminal are pressed by a terminal of the male connector to be bent toward an outer lateral side of the terminal groove to contact the elastic plate of the cover member. The present invention effectively improves the cross interference during high speed transmission, thereby achieving the Generation 5 performance requirement.

A contact device for receiving a plug end includes a first contact, which has a first coupling end and a first contact end, and a second contact, which has a second coupling end and a second contact end. The coupling ends are configured to electrically couple the respective contact to a receiving device, and the contact ends are configured to electrically connect the respective contact to a contact element of the plug end. The shortest distance between the first coupling end and the first contact end is not equal to the shortest distance between the second coupling end and the second contact end. The total length of the first contact is equal to, or is within a predetermined tolerance from, the total length of the second contact.

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.

A power communication electrical connector is provided, comprising: a plug and a socket which are matched and plugged for connecting a power source circuit or a high-power load circuit; wherein power source connectors and the signal connectors are respectively provided on both the plug and the socket, the power source connectors are for connecting a power source of the power source circuit or a high-power load of the high-power load circuit; the signal connectors are for connecting an external chip of the power source circuit or an external chip of the high-power load circuit, wherein a power ground of the power source connectors the a signal ground of the signal connectors are separately provided. In addition, an anti-spark power communication electrical connector is further provided.

A power communication electrical connector is provided, comprising: a plug and a socket which are matched and plugged for connecting a power source circuit or a high-power load circuit; wherein power source connectors and the signal connectors are respectively provided on both the plug and the socket, the power source connectors are for connecting a power source of the power source circuit or a high-power load of the high-power load circuit; the signal connectors are for connecting an external chip of the power source circuit or an external chip of the high-power load circuit, wherein a power ground of the power source connectors the a signal ground of the signal connectors are separately provided. In addition, an anti-spark power communication electrical connector is further provided.

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 module for a high-current plug and/or a high-current cable includes a coupling face coupling to a shield and an influencing device influencing an electromagnetic property of the shield.