The invention provides a printed circuit board (10) including a first electrically conductive track (210), wherein the printed circuit board (10) comprises a set (15) of two printed circuit board areas (100) both comprising a part of the first electrically conductive track (210), wherein printed circuit board (10) further comprises a perforation line (300) between the two printed circuit board areas (100) for customizing the printed circuit board (10) into two physically separated printed circuit board area comprising parts (1100), wherein the perforation line (300) is configured as a non-straight line, wherein the perforation line (300) comprises relative to one of the printed circuit board areas (100), and in a plane of the printed circuit board (10), a first projecting part (311) and a first recessed part (312), wherein the first recessed part (312) is recessed relative to the first projecting part (311), wherein the first electrically conductive track (210) is intercepted by the perforation line (300) at the first recessed part (312).

A manufacturing method of a processed resin substrate includes: preparing a resin substrate including a resin layer and a metal layer that covers at least a part of one surface of the resin layer; and forming a through hole in the resin substrate by irradiating the resin substrate with pulsed laser light. In the forming of the through hole, an interval of irradiation of the pulsed laser light at each point on the resin substrate is 5 msec or more.

A semi-flex component carrier includes a stack having at least one electrically insulating layer structure, at least one electrically conductive layer structure and a stress propagation inhibiting barrier. The stack defines at least one rigid portion and at least one semi-flexible portion. The stress propagation inhibiting barrier includes a plurality of stacked vias filled at least partially with electrically conductive material in an interface region between the at least one rigid portion and the at least one semi-flexible portion and configured to inhibit stress propagation between the at least one rigid portion and the at least one semi-flexible portion during bending.

An electronic assembly includes a first wafer including a stack of alternating first dielectric layers and first circuit layers, a flexible structure inclduing a second dielectric layer and a second circuit layer covered by the second dielectric layer, and a second wafer stacked upon the first wafer and including chip packages arranged in an array. The flexible structure includes a first region embedded in the first wafer and a second region connected to the first region and extending out from an edge of the first wafer. The chip packages are electrically coupled to the second circuit layer of the flexible structure through the first circuit layers of the first wafer.

A component carrier with a rigid portion, a flexible portion, a cavity defining the flexible portion next to the rigid portion, and at least one step in a transition portion between the rigid portion and the flexible portion in the cavity is disclosed.

A millimeter wave antenna and a process design of a millimeter wave antenna are provided. The millimeter wave antenna includes a substrate and an antenna attached to the substrate. The substrate includes a first region and a second region. A thickness of the first region is less than a thickness of the second region. The antenna is arranged on the first region. According to the present application, the millimeter wave antenna enables the substrate attached with the antenna to be as thin as possible, such that a medium structure of the first region of the substrate is changed, reducing an energy loss while a millimeter wave is being transmitted.

In the manufacture method of the present invention, an inner circuit structure is prepared, and a docking pad is formed on the first surface of the inner circuit structure. A release film is mounted on the first surface to cover the docking pad before mounting a build-up circuit structure upon the first surface. The release film and part of the build-up circuit structure above it are removed. The docking pad is therefore exposed and a docking opening is formed in the build-up circuit structure. The docking opening is for mounting a circuit board to be docked to form a circuit board module of the present invention.

Described are component carriers including a stepped cavity into which a stepped component assembly is embedded. The component carriers have (a) fully cured electrically insulating material originating from at least one electrically insulating layer structure of the component carrier and circumferentially surrounding the stepped component assembly and/or (b) an undercut in a transition region between a narrow recess and a wide recess of the stepped cavity. Further described are methods for manufacturing such component carriers.

A manufacturing method of a processed resin substrate includes: preparing a resin substrate including a resin layer and a metal layer that covers at least a part of one surface of the resin layer; and forming a through hole in the resin substrate by irradiating the resin substrate with pulsed laser light. In the forming of the through hole, an interval of irradiation of the pulsed laser light at each point on the resin substrate is 5 msec or more.

The invention provides a printed circuit board (10) including a first electrically conductive track (210), wherein the printed circuit board (10) comprises a set (15) of two printed circuit board areas (100) both comprising a part of the first electrically conductive track (210), wherein printed circuit board (10) further comprises a perforation line (300) between the two printed circuit board areas (100) for customizing the printed circuit board (10) into two physically separated printed circuit board area comprising parts (1100), wherein the perforation line (300) is configured as a non-straight line, wherein the perforation line (300) comprises relative to one of the printed circuit board areas (100), and in a plane of the printed circuit board (10), a first projecting part (311) and a first recessed part (312), wherein the first recessed part (312) is recessed relative to the first projecting part (311), wherein the first electrically conductive track (210) is intercepted by the perforation line (300) at the first recessed part (312).