A power delivery control module includes a first interface, a second interface and a controller. The first interface is configured to be coupled with a first external device. The second interface is configured to be coupled with a second external device. The second interface is a USB Type-C interface, and the first interface is not a USB Type-C interface. The controller is coupled with the first interface and the second interface. Wherein when the first interface is coupled with the first external device and the second interface is coupled with the second external device, the power delivery control module selectively transfers power from the first external device to the second external device or from the second external device to the first external device.

An interconnection system with a compliant shield between a connector and a substrate such as a PCB. The compliant shield may provide current flow paths between shields internal to the connector and ground structures of the PCB. The connector, compliant shield and PCB may be configured to provide current flow in locations relative to signal conductors that provide desirable signal integrity for signals carried by the signal conductors. In some embodiments, the current flow paths may be adjacent the signal conductors, offset in a transverse direction from an axis of a pair of conductors. Such paths may be created by tabs extending from connector shields. A compliant conductive member of the compliant shield may contact the tabs and a conductive pad on a surface of the PCB. Shadow vias, running from the surface pad to internal ground structures may be positioned adjacent the tip of the tabs.

An interconnection system with a compliant shield between a connector and a substrate such as a PCB. The compliant shield may provide current flow paths between shields internal to the connector and ground structures of the PCB. The connector, compliant shield and PCB may be configured to provide current flow in locations relative to signal conductors that provide desirable signal integrity for signals carried by the signal conductors. In some embodiments, the current flow paths may be adjacent the signal conductors, offset in a transverse direction from an axis of a pair of conductors. Such paths may be created by tabs extending from connector shields. A compliant conductive member of the compliant shield may contact the tabs and a conductive pad on a surface of the PCB. Shadow vias, running from the surface pad to internal ground structures may be positioned adjacent the tip of the tabs.

A modular electrical connector with broad-side coupled signal conductors in a right angle intermediate portion and edge coupled end portions. Broadside coupling provides balanced pairs for very high frequency operation, while edge coupling provides a high density interconnection system at low cost. Each module has separately shielded signal conductor pairs. The shielding is shaped to avoid or suppress undesirable propagation modes within an enclosure formed by shielding per module. Lossy material is selectively placed within and outside the shielding per module to likewise avoid or suppress unwanted signal propagation.

A modular electrical connector with broad-side coupled signal conductors in a right angle intermediate portion and edge coupled end portions. Broadside coupling provides balanced pairs for very high frequency operation, while edge coupling provides a high density interconnection system at low cost. Each module has separately shielded signal conductor pairs. The shielding is shaped to avoid or suppress undesirable propagation modes within an enclosure formed by shielding per module. Lossy material is selectively placed within and outside the shielding per module to likewise avoid or suppress unwanted signal propagation.

A connecting device configured to be installed on a first coaxial cable connector to facilitate connection of the first connector to a second connector and to maintain ground continuity across the connectors. In some embodiments, the connecting device includes a grounding element disposed in a gripping member, the grounding element including one or more projections configured to extend beyond an end of the gripping member to conductively engage an outer surface of the second connector.

In an example, a connector port assembly for use in an electronic device is disclosed. The connector port assembly may include a connector port, a fastener assembly and a flexible ring. The fastener assembly may fasten the connector port to a casing of the electronic device through at least one resilient member. The flexible ring may be disposed around an outer surface of the connector port. The fastener assembly and flexible ring may provide bend angle for the connector port.

In an example, a connector port assembly for use in an electronic device is disclosed. The connector port assembly may include a connector port, a fastener assembly and a flexible ring. The fastener assembly may fasten the connector port to a casing of the electronic device through at least one resilient member. The flexible ring may be disposed around an outer surface of the connector port. The fastener assembly and flexible ring may provide bend angle for the connector port.

A shielding element for a connector comprises a sheet-shaped section, a passageway formed in the sheet-shaped section, and a contacting tab disposed at the passageway. The contacting tab protrudes from the sheet-shaped section and has a sharp cutting edge at a free end of the contacting tab.

A shielding element for a connector comprises a sheet-shaped section, a passageway formed in the sheet-shaped section, and a contacting tab disposed at the passageway. The contacting tab protrudes from the sheet-shaped section and has a sharp cutting edge at a free end of the contacting tab.