A biostimulator, such as a leadless cardiac pacemaker, having a flexible circuit assembly, is described. The flexible circuit assembly is contained within an electronics compartment between a battery, a housing, and a header assembly of the biostimulator. The flexible circuit assembly includes a flexible substrate that folds into a stacked configuration in which an electrical connector and an electronic component of the flexible circuit assembly are enfolded by the flexible substrate. An aperture is located in a fold region of the flexible substrate to allow a feedthrough pin of the header assembly to pass through the folded structure into electrical contact with the electrical connector. The electronic component can be a processor to control delivery of a pacing impulse through the feedthrough pin to a pacing tip. Other embodiments are also described and claimed.

A power module includes a housing, a circuit component, and a package. The housing includes a main housing, a heat sink, and a fastening layer. A first outer surface of the main housing is provided with a groove. The fastening layer is disposed on a bottom surface of the groove. The heat sink is located on a side opposite to an orientation of the groove. The circuit component includes a heat dissipation surface and a pin. The heat dissipation surface is fastened to the fastening layer through welding. The pin extends out of the first outer surface in a direction away from the fastening layer. The package is configured to cover the circuit component, and to at least partially expose a distal end of the pin.

A circuit structure includes a first busbar, a wiring board located on the first busbar and having an open hole, a conductive raised part protruding into the open hole from the first busbar, and a first electronic component having a first connection terminal located on the wiring board. The first connection terminal is electrically connected to the raised part in the open hole.

An electronic device according to an embodiment includes first and second substrates, first and second conductors, and an electronic component. The first substrate includes a first connector portion, first pad portions, and a first transmission line. The first pad portions include a second pad portion, the first transmission line coupling the second pad portion and the first connector portion. The second substrate includes third pad portions. The third pad portions include a fourth pad portion and a fifth pad portion. The first conductor is coupled to the fourth pad portion and to the second pad portion. The second conductor is coupled to the fifth pad portion. The first electronic component has one end coupled to the first conductor and other end coupled to the second conductor.

A bi-directional solid state switch includes: a first bus bar; a second bus bar; a first solid state switch implemented on a first printed circuit board (PCB), the first solid state switch including: a first control terminal; a first terminal electrically connected to the first bus bar; and a second terminal; and a second solid state switch implemented on a second PCB, the second solid state switch including: a second control terminal; a third terminal electrically connected to the second terminal of the first solid state switch; and a fourth terminal electrically connected to the second bus bar.

A semiconductor device, including a first board, a second board having a plurality of through holes passing therethrough, and a plurality of external terminals that are respectively press-fitted into the plurality of through holes of the second board, one end portion of each external terminal passing through the corresponding through hole and being fixed to a front surface of the first board. The second board is a printed circuit board that further includes, in a top view thereof, a plurality of support regions, each having one of the plurality of through holes formed therein, and a plurality of buffer regions respectively surrounding the plurality of support regions, each buffer region having at least one buffer hole and at least one torsion portion formed therein, the at least one torsion portion being connected to the support region surrounded by each buffer region.

A semiconductor device, including a semiconductor module, a positioning member and a printed board. The semiconductor module includes a case that stores a semiconductor chip, a plurality of external terminals electrically connected to the semiconductor chip and extending upward from a front surface of the case, and a reference pin extending upward from the front surface of the case. The positioning member has a reference hole and a plurality of supporting holes penetrating therethrough. The printed board including a plurality of terminal holes that respectively correspond to the plurality of external terminals. The printed board is disposed on the front surface of the case via the positioning member. The plurality of external terminals of the semiconductor module are respectively attached to the plurality of terminal holes.

A semiconductor device includes a circuit board including an insulating layer having opposite front and rear surfaces, an electrode pad disposed on the front surface, a housing having an installation area for the circuit board, and a bonding material embedded in a recess within either a first area located at the rear surface of the insulating layer directly below an area of the circuit board in which the electrode pad is disposed, or at a second area located within the installation area of the housing and corresponding to the first area in a plan view.

A method for producing a printed circuit board structure comprising at least one insulation layer, at least one conductor layer, and at least one embedded component having a contact pad that has an outer barrier layer, in which structure at least two conductor paths/conductor layer are connected to at least two connections using vias, and each via runs from a conductor path/conductor layer directly to the barrier contact layer of the corresponding connection of the component.

Methods, apparatus and systems are described. An apparatus includes a module body made of a polymer material. The module body includes a mounting surface adjacent a potting area. At least two lead frame elements are embedded in the polymer material of the module body. Each of the at least two lead frame elements has a first terminal side and a second terminal side in the component potting area. An LED element is on the mounting surface of the module body and electrically coupled to the first terminal side of the at least two lead frame elements.