A device includes comprising first and second printed circuit boards. Walls couple the first and second printed circuit boards to each other and define a first cavity between the first and second printed circuit boards. Electric conductors associated with the walls electrically connect the the first and second printed circuit boards. An integrated circuit chip is mounted to a first surface of the first integrated circuit board in the first cavity. The integrated circuit chip is electrically connected to conductive tracks of the first surface of the first printed circuit board. Surface-mounted components are mounted on top of and in contact with conductive tracks of a first surface of the second printed circuit board. The first surfaces of the first and second printed circuit boards are arranged facing towards each other. The first and second printed circuit boards may form rigid components of a flex-rigid type printed circuit board.

An apparatus for automating the fabrication of a copper vertical launch (CVL) within a printed circuit board (PCB) includes a feed mechanism to feed and extrude copper wire from a spool of copper wire and a wire cutting and gripping mechanism to receive copper wire from the feed mechanism, cut and secure a segment of copper wire, insert the segment of copper wire into a hole formed within the PCB, solder an end of the segment of copper wire to a signal trace of the PCB, and flush cut an opposite end of the segment of the copper wire to a surface of the PCB. The wire cutting and gripping mechanism includes a wire cutter to flush cut the segment of copper wire and an integrated heated gripper device to receive the copper wire from the spool of copper wire and cut and grab a segment from copper wire.

Provided is a current detection device including a first stacked board; a second stacked board provided on a first region on the first stacked board; a third stacked board provided on a second region on the first stacked board; a magnetic measurement element provided in a third region on the first stacked board, the magnetic element provided between the first region and the second region; and a first coil provided on the magnetic measurement element or below the magnetic measurement element.

Electromagnetic shields for electronic devices, and particularly electromagnetic shields with bonding wires for sub-modules of electronic devices are disclosed. Electronic modules are disclosed that include multiple sub-modules arranged on a substrate with an electromagnetic shield arranged on or over the sub-modules. Bonding wires are disclosed that form one or more bonding wire walls along the substrate. The one or more bonding wire walls may be located between sub-modules of a module and about peripheral boundaries of the module. The electromagnetic shield may be electrically coupled to ground by way of the one or more bonding wire walls. Portions of the electromagnetic shield and the one or more bonding wire walls may form divider walls that are configured to reduce electromagnetic interference between the sub-modules or from external sources.

There is provided an electronic circuit apparatus in which the heat generated at an electronic component can be transferred to a heat spreader efficiently. An electronic circuit apparatus includes a dielectric substrate, an electronic component, a heat spreader, and a conductive via. The conductive via electrically and thermally connects the electronic component and the heat spreader. The conductive via extends from the first surface to at least an interior of the heat spreader and is in surface-contact with the heat spreader.

An electronic assembly that includes a rigid printed circuit board having an upper surface with a first plurality of lands. The electronic assembly further includes a flexible printed circuit board having a second plurality of lands on an upper surface. The lower surface of the flexible printed circuit board is directly attached to the upper surface of the rigid printed circuit board. The electronic assembly further includes a plurality of wires. Each of the wires is bonded to the first plurality of lands on the upper surface of the rigid printed circuit board and the second plurality of lands on the upper surface of the flexible printed circuit board.

A wiring substrate includes: an insulating substrate including a base portion comprising a through hole having a first opening and a second opening, and a frame portion located on the base portion; and a heat dissipator disposed on a side of the base portion that is opposite to the frame portion so as to block the second opening, wherein an inner surface of the through hole faces a side surface of the heat dissipator with a clearance being provided between the inner surface of the through hole and the side surface of the heat dissipator.

The disclosure provides an electronic assembly that includes: a carrier element, a circuit carrier having a number of electronic components, a circuit board, which is electrically conductively connected to the circuit carrier, and a covering element for covering the circuit carrier. The covering element is arranged on one flat side of the circuit board and the carrier element is arranged on an opposite flat side of the circuit board. The circuit board is welded respectively to the carrier element and to the covering element. The disclosure further relates to a method for producing such an electronic assembly.

Systems and methods for generating a virtual environment for implementing an integrated photonics assembly are presented. An example system can include one or more processors and a memory coupled with the processors, where the processor executes a plurality of modules stored in the memory. The plurality of modules can include a user interface module for deploying one or more virtual photonic integrated subcircuits within the virtual environment, in which the virtual environment is configured to enable coupling of at least two virtual photonic integrated subcircuits. The coupling of the virtual photonic integrated subcircuits can form a virtual integrated photonics assembly. The modules can include a library module comprising a plurality of virtual photonic integrated subcircuits. One or more virtual photonic integrated subcircuits can include a performance characteristic. The performance characteristic can represent a real-world performance characteristic of a pre-fabricated physical photonic integrated subcircuit corresponding to the virtual photonic integrated subcircuit.

A wide bandwidth circuit board arrangement includes two coplanar substrates separated by a predetermined gap, and at least one bond wire arranged across the gap and interconnecting a respective conducting microstrip line on a first side of each respective substrate. Further, the arrangement includes at least one open stub arrangement configured on the first side of each respective substrate, each open stub arrangement comprising a microstrip extending at an angle from an end of each conducting strip on each respective substrate. Finally, the arrangement includes a ground layer on a second side of each respective substrate, and a defected ground structure arranged on the second side of each respective substrate and laterally overlapping each respective open stub arrangement arranged on the first side.