A power control device is contained within a housing and has an electric current sensor configured to measure current passing through an electric outlet during a time period, a proximity sensor configured to detect a distance of an object relative to the electric outlet during the time period, a relay switch that can open or close to stop or conduct current through a circuit in the electric outlet in response to a command, and a wireless network interface in communication with the electric current sensor and the proximity sensor, the wireless network interface configured to transmit and receive data from the current sensor and the proximity sensor, to transmit commands to the relay switch, transmit the data to a computing device, and receive commands from the computing device.

An electronic device and a CIP (connector-in-package) package used therein. The CIP package can includes a semiconductor chip, an RF connector, and a carrier substrate. The carrier substrate is for carrying the semiconductor chip and the RF connector and electrically connected to the semiconductor chip and the RF connector to allow the semiconductor chip to transmit RF signal through the RF connector.

The present disclosure relates to a connector and method for connecting a coaxial cable to a printed circuit board. The connector comprises: a connector, which comprises a cavity penetrating the connector, such that the connector body comprises a first opening and a second opening; an inner contact arranged in the cavity of the connector body, wherein the first end of the inner contact extends from the first opening and the second end of the internal contact is located in the cavity; a plurality of outer contacts arranged on the end face of the connector body, which extend in a direction perpendicular to the end face; a dielectric spacer provided in the cavity of the connector body for separating the inner contact from the plurality of outer contacts; and a bushing element being attachable to the outer conductor of the coaxial cable to form an electrical connection between the plurality of outer contacts of the connector and the outer conductor of the coaxial cable. The connector further comprises a recess formed by a third opening provided on its side, wherein the recess includes an inner peripheral surface and a bottom surface with a hole, and the bushing element can be placed in the recess.

A ganged connector assembly includes: a housing; a plurality of first coaxial connectors mounted in the housing; a plurality of first coaxial cables, each attached to a respective one of the plurality of first coaxial connectors; and a second coaxial cable electrically connected with a first one of the first coaxial connectors, the second coaxial cable configured to transmit AISG signals to the first one of the first coaxial connectors.

This application provides a board-level architecture and a communications device. The board-level architecture includes a support board, a switch board, and a press fit component. The press fit component includes a cable, a first connector component press-fitted on a side edge of the support board, and a second press fit cable connector press-fitted on a side edge of the switch board. The first connector component includes a first press fit cable connector and a pluggable connector that is electrically connected to the first press fit cable connector, and the pluggable connector is farther from the support board than the first press fit cable connector. The first press fit cable connector is connected to the second press fit cable connector through the cable.

The present disclosure is generally directed to an RF connector assembly for use within a node of a broadband distribution network, and can receive a center conductor pin of a coaxial cable, e.g., via insertion by a technician, and electrically couple the center conductor pin to circuitry within the node, such as an amplifier. The RF connector assembly preferably also securely physically couples to the center conductor pin via a spring-biased arrangement (and thus by extension securely couples the coaxial cable to the housing of the node) which can supply a bias force to the center conductor pin in response to insertion of the same into the RF connector assembly. This advantageously eliminates the necessity of opening the housing of the node to couple/decouple the center conducting pin of the coaxial cable to the node.

A jumper cable assembly includes: a plurality of jumper cables, each having a first end terminated in a first connector and a second end terminated in a second connector; and a first mounting structure, the first connectors being mounted in the first mounting structure in a fixed arrangement relative to each other, the arrangement matching an arrangement of connectors of one of an antenna and a piece of cellular equipment to facilitate installation of the jumper cable assembly.

Provided is a wiring structure with which a module board of one mobile communication apparatus can be connected to a circuit board of another mobile communication apparatus by using an optimal wiring material. The present invention is provided with: a main board 2; a first module board 8; a first connector that can be fitted to a coaxial cable connector and a connector mounted on a flexible printed board and that is mounted on the first module board; a second connector 10 fitted to the first connector; and wiring materials 6a, 6b, 14a-14e that are attached to the second connector and electrically connect the main board and the first module board.

A power control device is contained within a housing and has an electric current sensor configured to measure current passing through an electric outlet during a time period, a proximity sensor configured to detect a distance of an object relative to the electric outlet during the time period, a relay switch that can open or close to stop or conduct current through a circuit in the electric outlet in response to a command, and a wireless network interface in communication with the electric current sensor and the proximity sensor, the wireless network interface configured to transmit and receive data from the current sensor and the proximity sensor, to transmit commands to the relay switch, transmit the data to a computing device, and receive commands from the computing device.

Disclosed embodiments include a modified M.2 interface that is configured to allow an increased current capacity on power-carrying pins. The power-carrying pins are implemented using an alloy that can sustain current levels in excess of those specified in the M.2 standard while remaining within M.2 standard specified temperature limits. Sockets and corresponding cards in embodiments are modified so that a card requiring the higher current capacity cannot fit into a legacy M.2 standard socket, while a legacy M.2 card can fit into a modified high current M.2 socket. Other embodiments may be described and/or claimed.