Various embodiments provide a flexible printed circuit comprising a substrate layer portion and an electrically-conductive layer portion. The electrically-conductive layer portion may be superimposed over the substrate layer portion. The substrate layer portion may have an opening formed therein and part of the electrically-conductive layer portion may be positioned over the opening to form a partially detachable tab. The tab may be for use in initiating separation of one portion of the flexible printed circuit from another portion of the flexible printed circuit. Various embodiments provide a corresponding method of fabrication of a flexible printed circuit. Various embodiments provide a corresponding method of fabrication of a plurality of electronic devices.

A connector for electrically connecting to conductive structures formed on a semiconductor device includes a core with first, second and third ground planes isolated from each other and signal vias and ground vias formed therein, conductive signal traces formed coplanar with the second ground plane and isolated from a conductive ground layer forming the second ground plane, where one or more conductive signal traces are shielded by the conductive ground layer and by the first and third ground planes. The connector includes a first set of contact elements electrically connected to signal vias that are electrically connected to first ends of the conductive signal traces and a second set of contact elements electrically connected to signal vias that are electrically connected to second ends of the conductive signal traces.

Provided are interconnects for interconnecting a set of battery cells, assemblies comprising these interconnects, methods of forming such interconnects, and methods of forming such assemblies. An interconnect includes a conductor comprising two portions electrically isolated from each other. At least one portion may include two contacts for connecting to battery cells and a fuse forming an electrical connection between these two contacts. The interconnect may also include an insulator adhered to the conductor and mechanically supporting the two portions of the conductor. The insulator may include an opening such that the fuse overlaps with this opening, and the opening does not interfere with the operation of the fuse. In some embodiments, the fuse may not directly interface with any other structures. Furthermore, the interconnect may include a temporary substrate adhered to the insulator such that the insulator is disposed between the temporary substrate and the conductor.

A circuit board comprises a row of solder pads adapted to be soldered to a row of contacts of a connector, a plurality of first conductive vias, and a plurality of second conductive vias. The contacts include a plurality of ground contacts and a plurality of signal contacts. The solder pads include a plurality of ground solder pads each soldered to a solder foot of one of the ground contacts and a plurality of signal solder pads each soldered to a solder foot of one of the signal contacts. The first conductive vias correspond to and are electrically connected to the ground solder pads and are electrically connected to each other by a first connection bar. The second conductive vias correspond to and are electrically connected to the ground solder pads and are electrically connected to each other by a second connection bar. The solder foot of each of the ground contacts is disposed between one of the first conductive vias and one of the second conductive vias.

A multi-layer printed circuit board (PCB) includes a laminate between a PCB heating core and a PCB signal core. The PCB heating core includes an electrically conductive resistive heating element upon a first core substrate. During a lamination cure PCB fabrication stage, a platen contacts the PCB and a power supply is electrically connected to the resistive heating element. The laminate is cured with heat transferred by the platen and heat from the resistive heating element. The PCB heating core may be located within an inner layer of the multi-layer PCB to normalize a thermal gradient across the multi-layer PCB that may otherwise occur during the laminate cure fabrication stage. As a result of the normalized thermal gradient, the degree of laminate cure and material characteristics of the cured laminate material are more consistent throughout the multi-layer PCB thickness.

An image pickup apparatus includes: an image pickup device including a light receiving surface, an opposite surface, and an inclined surface inclined at a first angle, and provided with light receiving surface electrodes on the light receiving surface; a cover glass; and a wiring board including a first main surface and a second main surface, and including wires each connected with each of the light receiving surface electrodes, back surfaces of the light receiving surface electrodes are exposed to a side of the opposite surface, distal end portions of the wires are flying leads bent at a second angle in a relation of a supplementary angle to the first angle and connected with the light receiving surface electrodes, and the second main surface at a distal end portion of the wiring board is directly fixed to the opposite surface arranged in parallel with the second main surface.

A method of manufacturing a wiring board includes a stacking process in which N (N is an integer equal to or greater than 2) wiring layers, end portions of which include linear conductor patterns, are stacked, with the end portions superimposed, via substrates (insulating layers) provided among the wiring layers and a laminated plate is manufactured and a removing process in which the insulating layers around the end portions of the conductor patterns of the laminated plate are removed to machine the end portions into N flying leads projecting from an end face.

Provided are interconnects for interconnecting a set of battery cells, assemblies comprising these interconnects, methods of forming such interconnects, and methods of forming such assemblies. An interconnect includes a conductor comprising two portions electrically isolated from each other. At least one portion may include two contacts for connecting to battery cells and a fuse forming an electrical connection between these two contacts. The interconnect may also include an insulator adhered to the conductor and mechanically supporting the two portions of the conductor. The insulator may include an opening such that the fuse overlaps with this opening, and the opening does not interfere with operation of the fuse. In some embodiments, the fuse may not directly interface with any other structures. Furthermore, the interconnect may include a temporary substrate adhered to the insulator such that the insulator is disposed between the temporary substrate and the conductor.

A multi-layer printed circuit board (PCB) includes a laminate between a PCB heating core and a PCB signal core. The PCB heating core includes an electrically conductive resistive heating element upon a first core substrate. During a lamination cure PCB fabrication stage, a platen contacts the PCB and a power supply is electrically connected to the resistive heating element. The laminate is cured with heat transferred by the platen and heat from the resistive heating element. The PCB heating core may be located within an inner layer of the multi-layer PCB to normalize a thermal gradient across the multi-layer PCB that may otherwise occur during the laminate cure fabrication stage. As a result of the normalized thermal gradient, the degree of laminate cure and material characteristics of the cured laminate material are more consistent throughout the multi-layer PCB thickness.

A plastic component with at least one electrical contact element has a plastic body and at least one electrical strip conductor, by which the electrical contact element can be electrically connected. Provisions are made for the plastic component to be manufactured by a combined injection molding and metal casting method, in which the plastic body is manufactured by an injection molding method and the at least one electrical strip conductor is manufactured by a metal casting or metal injection molding method one after another. The component formed last is molded onto the component formed first. Further, a method for manufacturing a corresponding plastic component is described.