A receptacle connector assembly includes an outer housing and a terminal module. The terminals module includes an insulator having a base and a mating tongue extending from the base and equipped with a plurality of contacts. The contacts include front contacting sections exposed upon the mating tongue and tail sections extending out of the base. The outer housing is of an insulative molding part or a metallic die cast, the terminal module is assembled in the outer housing, and thus a mating cavity is directly defined between the mating tongue and the outer housing.

Embodiments are directed towards apparatuses, methods, and systems for a memory module, e.g., a dual in-line memory module (DIMM) including a first lengthwise edge along the DIMM and a second lengthwise edge, opposite the first lengthwise edge, to couple the DIMM with a printed circuit board (PCB). In embodiments, the DIMM includes one or more notches along the first lengthwise edge, to removeably couple with one or more flexible supports located at least partially along a length or width of a chassis and to engage the notches to assist in retention of the DIMM in the chassis to reduce a shock and/or vibration associated with a load of a plurality of DIMMs on the PCB. In some embodiments, the one or more flexible supports are coupled to a support structure, such as a pole mounted or otherwise coupled to a panel of the chassis. Additional embodiments may be described and claimed.

A flexible multilayer construction (1000) for mounting a plurality of light emitting semiconductor devices (LESDs 100, 110, 120) includes a flexible dielectric substrate (200) comprising top (210) and bottom (220) major surfaces, and pluralities of corresponding electrically conductive top (300, 310, 320, 330) and bottom (500, 510, 520, 530) pads disposed on the top and bottom major surfaces, respectively. An electrically conductive via (400, 410, 420, 430) connects each pair of corresponding top and bottom pads, a side of each top pad partially overlapping a side of the corresponding bottom pad and a side of the substrate, such that in a plan view, each top pad fully overlaps the corresponding bottom pad.

The present invention relates to a substrate unit and a substrate assembly, and a camera module using the same. The present invention may comprise: a first substrate part having rigidity; a second substrate part stacked on one surface of the first substrate part and having flexibility; a third substrate part extending outwardly from the second substrate part and having flexibility; and a reinforcing part which is disposed at a portion where the edge portions of the first substrate part and the third substrate part meet, the reinforcing part having a recessed portion which is formed by recessing the first substrate part inwardly so as to inhibit interference between the first substrate part and the third substrate part. The present invention is capable of resolving the interference between a rigid PCB and a flexible PCB and the tearing thereof by providing a reinforcing part in a connection portion of the rigid PCB and the flexible PCB.

A printed circuit board (PCB) structure and mounting assembly for joining two PCBs. A first PCB has a top and bottom surface faces and a peripheral end face separating the top and bottom surface. The first PCB has one or more conductive wire ends exposed at a surface of the peripheral end face; the exposed conductive wire ends forming multiple separate electrical contacts across the thickness and length of the PEF surface. A second PCB has a top surface face and one or more conductive pads exposed at the top surface at locations corresponding to locations of the multiple electrical contacts. A surface mount solder material is disposed on one or more exposed conductive pads for electrically connecting with corresponding the multiple electrical contacts. The disposed solder material stably joins the PEF surface of the first PCB to the top surface of the second PCB in a relative perpendicular orientation.

A wiring board includes: a glass substrate serving as a substrate, which includes a first surface, a second surface which is opposite to the first surface, and a side surface; an input electrode serving an electrode, which is located close to a side of the first surface; an insulating layer disposed on the glass substrate; and a side wiring disposed so as to extend from the input electrode via the side surface to the second surface. An end of the insulating layer located close to the side is provided with a cutaway portion extending in an inward direction of the insulating layer, the input electrode is disposed in an entrance-side part of the cutaway portion, and the cutaway portion includes a bottom-side part constituting an inward area which is free of the input electrode.

A mounting structure has a first board, an extended portion which is extended from the end portion of the first board and has a smaller thickness than the first board, and a second board having a connection terminal connected to a connector. The second board is placed on the extended portion.

The pocket connector of the invention has been manufactured of a substrate, which is preferably flexible in at least one direction, of which three parts have been prepared, which are bent or assembled from three parts and joined together superimposed so that at least two opposite sides of the pocket connector have coupling apertures. Two flat cables or a connector for a flexible circuit board is connectable to these coupling apertures.

A cable assembly includes a printed circuit board having a first surface and a second surface. A first post and a second post extend from one side of the printed circuit board. A first signal pad, a second signal pad, and a first ground pad are each coupled to the first surface. A first cable has a first signal wire at least partially covered by a first insulator and a second signal wire at least partially covered by a second insulator. The first cable further has a first ground shield at least partially covering the first and second insulators. A first end of a first cable is mounted between the first and second posts. A conductive attachment couples the first ground shield to the first ground pad.

A SOM circuit board includes a main body having a first face surface, an opposing second face surface, a first side surface, an opposing second side surface, a first end surface, and an opposing second end surface. The first and second side surfaces have maximum lengths along a longitudinal direction which are greater than maximum lengths of the first and second end surfaces along a lateral direction. The SOM circuit board further includes a plurality of computing components, each of the plurality of computing components mounted on one of the first face surface or the second face surface. The SOM circuit board further includes an input/output connector mounted on the second face surface. The SOM circuit board further includes a plurality of mounting holes extending along the transverse direction through and between the first face surface and the second face surface.