A plug-in mobile peripheral component interconnect express module connector is disclosed, comprising a plastic body, and a first terminal set and a second terminal set disposed relatively in the plastic body. The plastic body includes transversely penetrated slots, an upper end surface of the slots has intermittently plural upper magazines, and a lower end surface has intermittently plural lower magazines. The first terminal set includes plural first elastic terminals inserted in the upper magazines, and the second terminal set includes plural second elastic terminals inserted in the lower magazines. Each first elastic terminal is opposed to each second elastic terminal, forming a holding gap. A motherboard is inserted between the first elastic terminals and the second elastic terminals from a side, and an MXM board is inserted between the first elastic terminals and the second elastic terminals from the other side.

A back-to-back ultra-slim module (USM) includes an inline USM (USMi) connector and a top mount USM (USMt) connector. The back-to-back USM assembly can be made as a double-sided module to allow a stacked module configuration to save system area. The stacked module has a USMi module inline with the system board on one side of the system board, and a USMt module vertically offset from the other side of the system board. The stacked module can have a thermal layer between the USMi module and the USMt module.

A cable includes a transmission line and a connector disposed on at least one end of the transmission line. The connector includes a housing to which the transmission line is connected and a terminal group that protrudes in a specific direction different from a direction parallel to a longest side of the housing. The terminal group is a terminal group for board-to-board connection.

A compact connector that mates with a complementary connector at high mating force. The connector (100) may have a housing (102) with a member (104) having a plurality of sides (106) and an opening (108) at a first side (110), and a frame (114) mounted to the member (104) from the first side (110) and having a plurality of walls (116) so as to bound the opening (108). The frame (114) may be made of a material that withstands forces to which the connector (100) may be exposed during mating. The member (104) may be made of a less robust material, such as plastic with thin walls (116) so as to enable a compact connector. The frame (114) and the member (104) may have engagement features, including latches, complementary chamfer and bevel features that may aid in mounting the frame (114) to the member (104) and locking features that resist dis-engagement of the frame (114) and the member (104).

Various embodiments of a wireless connector system are described. The system has a transmitter module and a receiver module that are configured to wirelessly transmit electrical energy and/or data via near field magnetic coupling. The wireless connector system is designed to increase the amount of wirelessly transmitted electrical power over a greater separation distance. The system is configured with various sensing circuits that alert the system to the presence of the receiver module to begin transfer of electrical power as well as undesirable objects and increased temperature that could interfere with the operation of the system. The wireless connector system is a relatively small footprint that is designed to be surface mounted.

High-speed connectors that save space in an electronic device, are simple to connect, and are readily manufactured. One example can provide a high-speed connector having high-speed connections. The high-speed connections can be integrated with low-speed connections in a board-to-board structure to save space in an electronic device. An example can provide high-speed connections that are simple to connect. The board-to-board structure can include a board-to-board plug, where each high-speed connection includes a high-speed contact having a lateral portion. The lateral portion can include right-angle tabs to guide a central conductor of a coaxial cable. The central conductor of each coaxial cable can be soldered to a corresponding lateral portion. Ground contacts for the board-to-board plug can include crimping portions to connect to an outer shield of each coaxial cable. These high-speed connectors can be readily manufactured by utilizing stamped contacts and molded housings.

A composite structure of a ceramic substrate, including a first ceramic substrate formed by crystal growth, which has a first surface and a second surface opposite to each other, and has only vertical via holes filled with conductive material, so that the first surface and the second surface of the first ceramic substrate are electrically connected; and a thin film substrate disposed on the second surface of the first ceramic substrate, and one of the surfaces is electrically connected to the second surface of the first ceramic substrate, and an electrical connection point is provided on the other surface of the thin film substrate to electrically connect an external element or another circuit board.

The present application relates to a unitary RF connector (1), intended for example to link two printed circuit boards (PCB1, PCB2), the unitary RF connector extending along a longitudinal axis (X), the connector being a unique piece with an electrically insulating block which serves as a rigid support for both flexible conductive elements whose central portions are rigidly respectively held therein for the central contact and on the outer wall of the block for the ground contact, and with an arrangement as crown for the plurality of free ends of the ground contact.

A power connector assembly transferring power between a supply connector assembly and a tap connector assembly includes a front interface module mated with the supply connector assembly and a rear interface module mounted to a host circuit board. The power connector assembly includes a power tap module between the front interface module and the rear interface module having power tap contacts each electrically connected to corresponding front and rear power contacts. Each power tap contact includes a tap interface exterior of the front housing and exterior of the rear housing configured to be terminated to the tap connector assembly. The power tap contact electrically connecting the front power contact and the tap connector assembly to transfer power from the supply connector assembly to the tap connector assembly.

An edge connector for coplanar coupling of two printed circuit boards (PCBs) comprises an elongated body and two end structures. The elongated body has a compression contact space and two PCB contact surfaces, each PCB contact surface having a plurality of contact positions. Portions of compression contacts positioned in the compression contact space extend through contact positions on both PCB contact surfaces. When a PCB edge surface contacts a PCB contact surface of the elongated body, an edge connection on the PCB edge surface contacts a compression contact, forming an electrical connection. Each end structure has two contact pairs, wherein each contact pair has attaching features that couple the edge connector to a PCB to maintain the electrical connection. When two PCBs are coupled to the edge connector, the compression contacts form electric paths for conducting power and/or communication between the two PCBs.