The present invention uses a photolithography process and an electroplating process to perform. TAV copper filling and patterning of the fabrication of the double side copper-plated layers to plate the double side copper-plated layers in advance at the TAV through holes to serve as a stress buffer layer of the aluminum nitride substrates. Then the subsequent pattern designs of the copper-plated layers are customized. According to the simulation theory calculations, it is proved that the stress which accumulates on the short-side of the copper-plated layer of the aluminum nitride substrate with the asymmetric structure may be effectively reduced to facilitate the improvement of the reliability of the aluminum nitride substrate.

A method for connecting a flexible printed circuit (FPC) to a battery module and a cell supervision circuit board (CSCB) is provided. The method includes: providing a coil of a continuous, strip-shaped FPC; unwinding a first section of the FPC from the coil, positioning the first section of the FPC over a first contact portion of the battery module, and welding a conductive structure of the FPC in the first section to the first contact portion of the battery module; unwinding a second section of the FPC from the coil, positioning the second section of the FPC over a contact pad of the CSCB, and welding the conductive structure of the FPC in the second section to the contact pad of the CSCB; and separating the first section and second section of the FPC from the coil of the FPC.

A printed circuit board includes an insulating layer, a pad, and a via fill. The insulating layer includes a via hole. The pad is formed in the insulating layer such that an intermediate portion thereof is exposed by the via hole. The pad includes a through hole formed in the intermediate portion. The via fill is formed in the via hole, configured to fill the through hole, and coupled to the intermediate portion.

A wiring board includes: a flexible printed circuit board that includes: a base having a first opening; a wiring pattern formed on the base; and a cover lay that includes an adhesive layer adhering to the wiring pattern and that has a second opening; and a metal cover that covers at least a part of the first opening from below. The wiring pattern contacts the metal cover through the first opening, and is bonded to the metal cover. At least a part of the second opening overlaps the first opening in a plan view. A part of the cover lay overlaps the first opening in a plan view.

Embodiments include an interconnectable circuit board array. The interconnectable circuit board array includes a plurality of interconnectable circuit boards coupled together with a plurality of board to board connectors. The board to board connectors include a first lateral side conductor and a second lateral side conductor to provide electrical communication between the connect circuit boards. The board to board connectors are configured such that when two adjacent circuit boards are bent in a lateral plane with respect to one another to form an angle, one of the lateral side conductors is contracted, one of the lateral side conductors is expanded, or one of the lateral side conductors is contracted and the other lateral side conductor is expanded. Other embodiments are also included herein.

This publication discloses an electronic module, comprising a first conductive pattern layer and a first insulating-material layer on at least one surface of the first conductive pattern layer, at least one opening in the first insulating-material layer that extends through the first insulating-material layer, a component having a contact surface with contact terminals, the component being arranged at least partially within the opening with its contact terminals electrically coupled to the first conductive pattern layer, a second insulating-material layer provided on the first insulating-material layer, and a conductive pattern embedded between the first and second insulating material layers. This publication additionally discloses a method for manufacturing an electronic module.

The invention relates to a circuit board (1), preferably for a circuit for operating a lighting means, comprising a retaining bow (2), which is arranged on a planar top side (11) of the circuit board (1) and mechanically connected to the circuit board (1); and comprising a through-bore (3), which is arranged at least partially below the retaining bow (2); wherein the through-bore (3) has at least one taper (31) and wherein a housing (5) for protecting the circuit board (1) can be mechanically fastened by means of the retaining bow (2) and the taper (31). The retaining bow (2) is arranged on the circuit board (1) by means of a solder joint (32). The invention further relates to a system for a circuit for operating a lighting means and to a method for fastening a housing (5) to a circuit board (1).

Substrates configured to route electrical signals may include a first dielectric material and an electrically conductive material located on a first side of the first dielectric material. A second dielectric material may be located on a second, opposite side of the first dielectric material. A series of voids may be defined by the second dielectric material extending from the first dielectric material at least partially through the second dielectric material. Footprints of at least some of the voids of the series of voids may at least partially laterally overlap with the electrically conductive material.

An example sensor interposer employing castellated through-vias formed in a PCB includes a planar substrate defining a plurality of castellated through-vias; a first electrical contact formed on the planar substrate and electrically coupled to a first castellated through-via; a second electrical contact formed on the planar substrate and electrically coupled to a second castellated through-via, the second castellated through-via electrically isolated from the first castellated through-via; and a guard trace formed on the planar substrate, the guard trace having a first portion formed on a first surface of the planar substrate and electrically coupling a third castellated through-via to a fourth castellated through-via, the guard trace having a second portion formed on a second surface of the planar substrate and electrically coupling the third castellated through-via to the fourth castellated through-via, the guard trace formed between the first and second electrical contacts to provide electrical isolation between the first and second electrical contacts.

A method for producing a waveguide in a multilayer substrate involves producing at least one cutout corresponding to a lateral course of the waveguide in a surface of a first layer arrangement comprising one or a plurality of layers. A metallization is produced on surfaces of the cutout. A second layer arrangement comprising one or a plurality of layers is applied on the first layer arrangement. The second layer arrangement comprises, on a surface thereof, a metallization which, after the second layer arrangement has been applied on the first layer arrangement, is arranged above the cutout and together with the metallization on the surfaces of the cutout forms the waveguide.