Provided is a substrate terminal-equipped printed circuit board having configured to enable a substrate terminal to be fixed to a printed circuit board without using a pedestal, and to reduce the pressure and the insertion force applied to an inner surface of a through hole when the substrate terminal is press-fitted therein. A conducting portion of a substrate terminal includes: a press-fitted portion disposed at a proximal end portion thereof and is press-fitted into a through hole; and a loosely inserted portion that extends from the press-fitted portion to a distal end portion thereof, has a narrower width than the press-fitted portion, and is inserted into the through hole with a gap therebetween, and the press-fitted portion of the conducting portion is in pressure contact only with printed wiring provided on a surface layer of the printed circuit board and with an insulating layer located immediately below the printed wiring.

A multilayer bus board comprising a multilayer stacked assembly including a plurality of electrically conductive first layers, and at least one second dielectric layer disposed between adjacent first layers; and a frame formed of a dielectric material, the frame encapsulating at least a portion of the multilayer stacked assembly and mechanically maintaining the first and second layers in secure aligned abutting relation.

An RF connector includes a conductive pin for carrying an RF signal. The conductive pin has a first longitudinal end that serves to interface with a male RF connector to receive the RF signal. The pin also includes a second longitudinal end for connecting with a printed circuit board (PCB). The second longitudinal end may be tapered, and the pin may have a groove formed above the tapered end. A housing encircles the conductive pin. The housing is shaped and sized to accept the male RF connector. A grounding element may be positioned on the bottom of the housing. The grounding element is to contact the PCB when the connector is connected to the PCB. The grounding element may be ring-shaped and soldered to the housing or epoxied to the housing.

According to exemplary embodiments, a tapered surface interconnect is formed on a printed circuit board (PCB). A compliant pin of an electrical connector may be coupled to the tapered surface interconnect and soldered thereto. The surface interconnect may be formed by drilling through one or more layers of the PCB. The depth of the surface interconnect may be shorter than a height or a thickness of the PCB. The surface interconnect may have a tapered side wall to allow for a better fit with a tapered compliant pin. The inclination of the side wall of the surface interconnect may be linear or concave. The intersection between the tapered sidewall and the bottom of the surface interconnect may be rounded to minimize pin insertion issues and may allow for easier solder flux evacuation. The compliant pin may be soldered into place upon being coupled to the tapered surface interconnect.

An adaptor board may include a multi-layer circuit board having at least three layers, namely a first board layer, a second board layer, and a third board layer. A first plurality of cable contacts may be provided at the first board layer, and a second plurality of cable contacts may be provided at the third board layer.

An electronic control connector (30) including at least an input orifice (32a), at least a fixing leg (33) and at least a terminal (34), the terminal (34) being inserted inside the input orifice (32a), the electronic control connector (30) being fixed to a printed circuit board (10) of an electronic control (50), by a fixing between the fixing leg (33) and a fixing orifice (16) disposed on the printed circuit board (10) of the electronic control (50), the fixing of the electronic control connector (30) to the printed circuit board (10) also establishing an electrical connection between the terminal (34) of the electronic control connector (30) and the tracks of the printed circuit board (10) of the electronic control (50).

A socket pin for electrically connecting a semiconductor substrate to a test substrate, comprising: a pin head; a pin body configured to support the pin head; and a length adjusting part provided below the pin body; wherein: the length adjusting part comprises at least a portion protruding from the pin body and a resilient structure; and the length adjusting part is movable to change a length of the portion protruding from the pin body as the resilient structure distorts.

An adaptor board may include a multi-layer circuit board having at least three layers, namely a first board layer, a second board layer, and a third board layer. A first plurality of cable contacts may be provided at the first board layer, and a second plurality of cable contacts may be provided at the third board layer.

According to exemplary embodiments, a tapered surface interconnect is formed on a printed circuit board (PCB). A compliant pin of an electrical connector may be coupled to the tapered surface interconnect and soldered thereto. The surface interconnect may be formed by drilling through one or more layers of the PCB. The depth of the surface interconnect may be shorter than a height or a thickness of the PCB. The surface interconnect may have a tapered side wall to allow for a better fit with a tapered compliant pin. The inclination of the side wall of the surface interconnect may be linear or concave. The intersection between the tapered sidewall and the bottom of the surface interconnect may be rounded to minimize pin insertion issues and may allow for easier solder flux evacuation. The compliant pin may be soldered into place upon being coupled to the tapered surface interconnect.

According to exemplary embodiments, a tapered surface interconnect is formed on a printed circuit board (PCB). A compliant pin of an electrical connector may be coupled to the tapered surface interconnect and soldered thereto. The surface interconnect may be formed by drilling through one or more layers of the PCB. The depth of the surface interconnect may be shorter than a height or a thickness of the PCB. The surface interconnect may have a tapered side wall to allow for a better fit with a tapered compliant pin. The inclination of the side wall of the surface interconnect may be linear or concave. The intersection between the tapered sidewall and the bottom of the surface interconnect may be rounded to minimize pin insertion issues and may allow for easier solder flux evacuation from the surface interconnect during the soldering process. The compliant pin may be soldered into place upon being coupled to the tapered surface interconnect.