A circuit board with a connector connection for the direct contacting with a connector, wherein the connector connection is formed on the front side of the circuit board with a contact pin that is arranged centrally in a blind hole while forming a circular ring-shaped cylindrical insertion space and that has an inner hole with a first contact zone of an inner conductor for contacting an inner conductor of the connector. A second contact zone of an outer conductor is arranged in the insertion space for contacting an outer conductor of the connector.

A high-speed transmission circuit comprises, as part of a signal path, a connector pin disposed on a pad that comprises an unused pad region. The unused pad region is not considered part of the signal path but is part of a resonant sub-circuit. In various embodiments, by properly adjusting the dimensions of the pad region and other structures in the high-speed transmission circuit, resonant frequencies of the sub-circuit are shifted to a frequency range that is outside of the frequency range of interest in the signal path, thereby, reducing insertion loss and increasing signal integrity without compromising mechanical stability.

A first insulating layer, a conductor layer included on a first main surface, an electronic component included on the first main surface and a second insulating layer stacked on the first insulating layer are included, a stacking direction of the first insulating layer and the second insulating layer is the same as a stacking direction of a first electrode layer, a second electrode layer, and the dielectric layer in the electronic component, and a height position of a main surface of the electronic component on an opposite side from a side of the first main surface is different from a height position of a main surface of the conductor layer adjacent to the electronic component on an opposite side from a side of the first main surface in the stacking direction.

The present disclosure relates to a structure for electrically-connecting an external conductor. The structure comprises a wiring-substrate comprising a stack based arrangement of a plurality of layers, wherein said layers are defined as electrically conducting layers and insulating layer. A rivet is supported from the wiring substrate and comprises an embedded portion within the wiring substrate. The embedded portion comprises: an upper section extending through the stack of the plurality of layers, and, a bottom section extending laterally with reference to the upper section. A portion protruding from wiring substrate is provided for receiving an external-conductor and for thereby electrically connecting with the wiring substrate.

Disclosed embodiments include folded, top-to-bottom interconnects that couple a die side of an integrated-circuit package substrate, to a board as a complement to a ball-grid array for a flip-chip-mounted integrated-circuit die on the die side. The folded, top-to-bottom interconnect is in a molded frame that forms a perimeter around an infield to receive at least one flip-chip IC die. Power, ground and I/O interconnections shunt around the package substrate, and such shunting includes voltage regulation that need not be routed through the package substrate.

An electronic control unit includes a casing and a cover which are mutually bonded. A drive circuit board which drives a motor unit is fixed to the cover and, on the other hand, a control circuit board which controls the drive circuit board is fixed to the casing. An electrical connector which supplies an electric power to each board and a motor unit is attached on an opening section of the casing. First power supply terminals of this electrical connector and the motor unit and second power supply terminals of the drive circuit board are directly electrically connected by a bonding of both of casing and the cover.

A method and apparatus for multiple flexible circuit cable attachment is described herein. Gold bumps are bonded on interconnection pads of a substrate to create a columnar structure and solder or conductive epoxy is dispensed on the flexible cable circuit. The substrate and flexible cable circuit are aligned and pressed together using force or placement of a weight on either the substrate or flexible cable circuit. Appropriate heat is applied to reflow the solder or cure the epoxy. The solder wets to the substrate pads, assisted by the gold bumps, and have reduced bridging risk due to the columnar structure. A nonconductive underfill epoxy is applied to increase mechanical strength.

A method and apparatus for multiple flexible circuit cable attachment is described herein. Gold bumps are bonded on interconnection pads of a substrate to create a columnar structure and solder or conductive epoxy is dispensed on the flexible cable circuit. The substrate and flexible cable circuit are aligned and pressed together using force or placement of a weight on either the substrate or flexible cable circuit. Appropriate heat is applied to reflow the solder or cure the epoxy. The solder wets to the substrate pads, assisted by the gold bumps, and have reduced bridging risk due to the columnar structure. A nonconductive underfill epoxy is applied to increase mechanical strength.

An elongate, three dimensional, conductive, micro lattice truss structure has parallel layers of resilient strands so that the truss structure maintains structural integrity during end-to-end compression which shortens its uncompressed length. The resiliency of the micro lattice truss structure enables the truss structure to return to substantially its uncompressed length when the compression is removed. The truss structure is adapted to provide a resilient electrical connection between two opposing conductive areas on parallel spaced-apart printed circuit boards when the distal ends of the truss structure engage and are compressed between the two areas.

An electronic component includes an element body, an external electrode, and a metal terminal. In the metal terminal, a base includes a first surface and a second surface opposing each other, and a pair of third surfaces coupling the first surface and the second surface. A first metal layer is disposed on the first surface and connected to solder with which the external electrode and the metal terminal are connected together. A second metal layer is disposed on the second surface. A coating layer is disposed on each of the third surfaces. The first metal layer and the second metal layer each include an outermost layer containing Sn. Each of the coating layer includes an outermost layer lower in solder wettability than the respective outermost layers of the first metal layer and the second metal layer.