An apparatus includes a printed circuit board (PCB). The PCB includes a plurality of through-holes extending through the PCB between a PCB first surface and a PCB second surface that opposes the PCB first surface, where each through-hole includes a via extending from the PCB first surface to a depth within the through-hole that is distanced from the PCB second surface. An integrated circuit surface mount is connected at the PCB first surface with vias of the through-holes, and a cable interconnect assembly is surface mount connected at the PCB second surface. The cable interconnect assembly includes a plurality of contact pins, each contact pin extending within a corresponding through-hole and having a sufficient dimension to engage and electrically connect with the via of the corresponding through-hole so as to facilitate exchange of an electrical signal between the integrated circuit and the cable interconnect assembly.

A method for producing a printed circuit board is disclosed, In the method, a slot is formed in a substrate having at least three layers with the slot extending through at least two of the layers. The slot has a length and a width with the length being greater than the width. The sidewall of the substrate surrounding the slot is coated with a conductive layer. Then, the conductive layer is separated into at least two segments that are electrically isolated along the side wall of the substrate.

A method of forming a multi-layer circuit on a curved substrate includes forming, by a laser direct structuring process, a first layer of the multi-layer circuit on a first surface of the curved substrate. The method includes applying a first layer of paint to the first layer of the multi-layer circuit. The method includes forming, by the laser direct structuring process, a second layer of the multi-layer circuit on the first layer of the paint and electrically coupled to the first layer of the multi-layer circuit. The method includes applying a second layer of paint over the second layer of the multi-layer circuit and forming, by the laser direct structuring process, a third layer of the multi-layer circuit on the second layer of the paint and electrically coupled to the second layer of the multi-layer circuit.

Electronic device such as a camera for a vehicle, including: a supporting frame, a main electronic substrate, provided with at least one electric or electronic component or circuit and coupled to the supporting frame; a secondary electronic substrate, provided with at least one electric or electronic component or circuit and coupled to the supporting frame; wherein the supporting frame has at least one main projecting tab and at least one secondary projecting tab, each capable to occupy a non-twisted position or a twisted position, wherein the main projecting tab, when in the twisted position, is providing an attachment of the main electronic substrate to the supporting frame, and wherein the secondary projecting tab, when in the twisted position, is providing an attachment of the secondary electronic substrate to the supporting frame.

In an embodiment, a 3D-printed electrical structure such as an electromagnetic bandgap is provided. The structure includes a dielectric material with an embedded electrical interconnect that functions like a via and electrically connects a first surface of the dielectric material with a second surface of the dielectric material such as a ground plane. Unlike conventional vias, the embedded interconnect is not limited to straight lines and can take a variety of shapes and paths in the dielectric material allowing for the electrical interconnect to have a longer length than the thickness of the dielectric material. Increasing the length of the electrical interconnect increases the inductance of the electrical interconnect which in turn increases the bandwidth and reduces the frequency of the electrical structure without an increase in the height of the dielectric material.

The present disclosure provides a circuit board. The circuit board may include a number of stacked core boards each having a top surface. At least part core boards of the number of stacked core boards may include circuit layers at top surfaces thereof. A groove may be defined through the at least part core boards. A conductive material may be received in the groove configured to couple to the circuit layers of at least two core boards. A cross section of the groove may include a length in a first direction and a length in a second direction, and the length in the first direction may be greater than the length in the second direction. Electroplating solution may capable of contacting any portions of the groove to electroplate, to form the conductive material.

The present disclosure relates to the method of manufacturing circuit having lamination layer using LDS (Laser Direct Structuring) to ease the application on surface structure for applied product of various electronic circuit and particularly, in which can form circuit structure of single-layer to multiple-layer on the surface of injection-molded substrate in the shape of plane or curved surface, metal product, glasses, ceramic, rubber or other material.

An circuit board assembly includes a first circuit board, a second circuit board stacked with the first circuit board, and a connection plate connected between the first circuit board and the second circuit board. The connection plate includes a signal transmission part and at least one ground part at a spacing to the signal transmission part. The ground part can be used as a reference ground for a signal transmitted by the signal transmission part, so that the characteristic impedance of the signal transmission part is controllable, and the signal transmitted by the signal transmission part has strong continuity, thereby maintaining good matching performance and reducing an insertion loss caused by characteristic impedance mismatch.

Provided is an example of a technology capable of accurately controlling impedance.

Provided is a substrate including a first through hole that penetrates a substrate from a first face to a second face of the substrate, and is electrically connected to a transmission line through which a signal is transmitted, a second through hole that is provided adjacent to the first through hole in plan view of the substrate, penetrates the substrate from the first face to the second face, and is electrically connected to a ground, and an adjustment unit that adjusts a distance between the first through hole and the second through hole in plan view of the substrate to adjust an impedance of a connection end of the first through hole with the transmission line.

A component carrier includes a stack comprising at least one electrically insulating layer structure and/or at least one electrically conductive layer structure, a component embedded in the stack, and at least one stress relief opening formed in each of the at least one electrically conductive layer structure arranged in the stack on one side of the component so that a portion of the stack extending from an exterior main surface of the component carrier up to a main surface of the component on said side and including the at least one stress relief opening is free of electrically conductive material.