An interposer includes a housing having a plurality of through-holes penetrating a first surface and a second surface and a signal contact pair composed of a pair of signal contacts. Each of the signal contacts includes a base portion press-fitted in one of the through-holes, a first contact beam extending from the base portion beyond the first surface, and a second contact beam extending from the base portion beyond the second surface. The pair of signal contacts are positioned adjacently to each other widthwise and are each asymmetrical with respect to a width direction. The signal contact pair has a plane-symmetrical shape with respect to the width direction.

A separable and reconnectable connector for semiconductor devices is provided that is scalable for devices having very small contact pitch. Connectors of the present disclosure include signal pins shielded by pins electrically-coupled to ground. One or more signal pins in a contact array are electrically-shielded by at least one ground pin coupled to a ground plane. Embodiments thereby provide signal pins, either single-ended or a differential pair, usable to transmit signals with reduced noise or cross-talk and thus improved signal integrity. Embodiments further provide inner ground planes coupled to connector ground pins to shield pairs of differential signal pins without increasing the size of the connector. Inner grounding layers can be formed within isolation substrates incorporated into connector embodiments between adjacent pairs of signal pins. These buried ground layers provide additional crosstalk isolation in close proximity to signal pins, resulting in improved signal integrity in a significantly reduced space.

An interposer configured for connecting offset arrays of signal pads on parallel surfaces. Contacts of the interposer have mating portions with multiple beams. One of the beams makes contact with a pad on a first of the surfaces and is deflected when the surfaces are pressed together with the interposer between them. A second of the beams is positioned so that the first beam presses into that second beam as the first beam deflects. The second beam may contact a central location on the first beam. An electrical path through the contact from a pad on the first surface to a pad on the second surface may be shorter when the first beam is pressed into the second beam than through the first beam alone. A shorter path may improve signal integrity. Moreover, the spring force of the contact may be set by the second beam.

A circuit structure is provided to which an electronic component can be easily mounted (electrical connection of terminals). A circuit structure that includes a substrate provided with a conductive pattern on one face thereof; a conductive member fixed to the other face of the substrate; an electronic component that has first terminals and of a plurality of terminals, that are electrically connected to the conductive member, and a second terminal of the plurality of terminals that is electrically connected to the conductive pattern provided on the substrate; and a relay member for electrically connecting the second terminal and the conductive pattern provided on the substrate, at least a portion of the relay member being fixed to the conductive member via an insulating material.

An electronic device including a stretchable/contractible base and a wiring formed on the base, the wiring being divided into a first region having a shape extending in a proceeding direction and a second region in which the proceeding direction is curved. The wiring includes a first conductive layer and a second conductive layer formed of a material that makes the second conductive layer easier to be curved than the first conductive layer. The first conductive layer is formed in the first region and the second conductive layer is formed in the second region.

A component carrier is illustrated and described. The component carrier has i) a stack with at least one electrically conductive layer structure and/or at least one electrically insulating layer structure, and ii) at least one elastic element attached to the stack and configured to reversibly connect the component carrier with a further component carrier by elastically deforming the at least one elastic element and essentially not deforming the stack and the further component carrier.

The invention provides a printed circuit board assembly (1) comprising (i) an at least partly folded flexible printed circuit board (100), and (ii) an at least partly folded support (200), wherein:—the at least partly folded flexible printed circuit board (100) comprises a first PCB region (110) and a second PCB region (120), wherein at least part of the second PCB region (120) is configured folded over at least part of the first PCB region (110);—the at least partly folded support (200) is configured to support at least part of the at least partly folded flexible printed circuit board (100), wherein the at least partly folded support (200) comprises a first support region (210) and a second support region (220), wherein at least part of the second support region (220) is configured folded over at least part of the first support region (210), wherein at least part of the at least partly folded flexible printed circuit board (100) is configured between the first support region (210) and the second support region (220), and wherein the at least partly folded support (200) is configured to maintain the at least partly folded flexible printed circuit board (100) folded.

An electronic device may include: a printed circuit board (PCB); a plurality of electronic components electrically connected to the PCB; and a connection member comprising a first portion fixed to one of the PCB and an electronic component and a second portion magnetically connected to the other one of the PCB and the electronic component. The second portion of the connection member may be moveably connected to the first portion. The connection member may further include a stopper, and may be designed to minimize the repulsive force provided by the connection member when excessive pressure is applied to the electronic device.

Generally, this disclosure provides systems, devices and methods for improved electrical coupling of multiple ground planes of a device. The device may include a plurality of ground planes and an electrically conductive ground clip. The ground clip may include a base portion configured to secure the ground clip to the device and a plurality of spring fingers. Each of the spring fingers may be configured to contact and electrically couple to one of the plurality of ground planes, wherein the ground clip is to provide a conduction path between each of the spring fingers. One of the spring fingers may pass through an opening or cut-through in a first ground plane to contact a second ground plane. The device may be a mobile communication or computing platform.

A resilient electrical connector assembly includes a base PCB and stacked layers of interconnected resilient conductive structures where each structure has at least two resilient conductive strips and at least two conductive contacts. One contact is integrated with a conductive path on the base PCB and another contact pad is positioned to establish a conductive path with a target PCB when the latter is mounted parallel to the base PCB. The resilient conductive strips flex due to a compressive force exerted between the base PCB and target PCB on the stacked layers. The resilient conductive structures are formed by depositing metal to sequentially form each of the stacked layers with one contact being initially formed in engagement with the conductive path on the base PCB.