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.

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 medical sensor patch connector assembly can include a medical patch having a first side, a second side opposite the first side, and a hole connecting the first side and the second side. The medical sensor patch connector assembly can include a connector including a first clamping member having a first contact surface in contact with the first side of the medial patch and a tab protruding through the hole in the medical patch. The connector can include a second clamping member having a second contact surface in contact with the second side of the medical patch.

A medical sensor patch connector assembly can include a medical patch having a first side, a second side opposite the first side, and a hole connecting the first side and the second side. The medical sensor patch connector assembly can include a connector including a first clamping member having a first contact surface in contact with the first side of the medial patch and a tab protruding through the hole in the medical patch. The connector can include a second clamping member having a second contact surface in contact with the second side of the medical patch.

A socket connector includes a housing having a top, a bottom, a first side wall and a second side wall forming cavities that receive power sockets. The housing includes pin access openings through the bottom that receive power pins mated to the power sockets. Each power socket includes a cable socket receiving a power cable and a pin socket that receives the power pin. The power socket electrically connects the power cable and the power pin. The socket connector includes latches each having a latch release and a latch arm operably coupled to the latch release. The latch arm extends along the corresponding pin access opening and includes a latching surface aligned with the pin access opening configured to engage the power pin to retain the power pin in the housing. The release button is actuated to release the latch arm from the power pin and allow removal of the power pin from the housing.

An electrical assembly may include a circuit board, a terminal header connected to the circuit board and including a plurality of aperture, and/or a plurality of electrical terminals connected to the terminal header. The plurality of electrical terminals may include a first electrical terminal having a first terminal configuration and/or a second electrical terminal having a second terminal configuration. The plurality of apertures may include a first aperture, a second aperture, and/or a third aperture. The first electrical terminal may include a first terminal first tail disposed at least partially in the first aperture. The second electrical terminal may include a second terminal first tail disposed at least partially in the second aperture. The second electrical terminal may include a second terminal second tail disposed at least partially in the third aperture.

An electrical assembly may include a circuit board, a terminal header connected to the circuit board and including a plurality of aperture, and/or a plurality of electrical terminals connected to the terminal header. The plurality of electrical terminals may include a first electrical terminal having a first terminal configuration and/or a second electrical terminal having a second terminal configuration. The plurality of apertures may include a first aperture, a second aperture, and/or a third aperture. The first electrical terminal may include a first terminal first tail disposed at least partially in the first aperture. The second electrical terminal may include a second terminal first tail disposed at least partially in the second aperture. The second electrical terminal may include a second terminal second tail disposed at least partially in the third aperture.

Provided are terminal-free connectors for flexible interconnect circuits. A connector comprises a housing chamber defined by at least a first side wall and a second side wall oppositely positioned about the base. An edge support is positioned at each of the first side wall and the second side wall. The edge supports allow for precise placement of the flexible interconnect circuit inside the housing chamber. A cover piece is coupled to the base via a first hinge, and is configured to move between a released position and a clamped position. The cover piece includes a clamp portion securing the flexible interconnect circuit against the edge supports in the clamped position. A slider may be configured to move between an extended position and an inserted position within the housing chamber, and may include a convex upper surface configured to urge the flexible interconnect circuit upwards in the inserted position.

A cable termination assembly configured for mounting to an interior portion of a printed circuit board. The cable termination assembly has a frame shaped to receive a paddle card to which a plurality of cables are terminated. A lid, when closed, may force the paddle card into contact with an interposer, which in turn may be pressed into a printed circuit board on which the cable termination assembly is mounted. Electrical signals may pass between the cables and traces in the printed circuit board via the paddle card and interposer. The termination assembly may be mounted near a processor or other high speed component on the printed circuit board, enabling high speed signals to be coupled with low loss between a periphery of the printed circuit board, or even a location off the printed circuit board, and the high speed component.

Electrical connector systems and methods create an electrical connection between a flexible circuit (FC) and a metal terminal of another connector. A reliable electrical connection is achieved with a low-cost tin contact plating, by an automatic FC to metal terminal wiping action with contact force, during the connector to FC assembly process. The connector to FC assembly process is also well suited for automated robotic assembly, which can save costs compared to manual assembly/installation.