A circuit board pad resonance control system includes a board. A signal transmission line is included on the board. A plurality of connector pads are positioned on the board. A first connector pad receives the signal transmission line adjacent a first end of that connector pad. The first connector pad includes a mounting surface that mounts directly to a coupling element that is configured to couple a subsystem to the board, and reduces a resonance that is produced by an open portion of a signal transmission path that is created when the coupling element is directly mounted to the mounting surface of the first connector pad in a first orientation. In a specific example, the mounting surface may include a plurality of protrusions, a plated surface, and/or a mask that reduces the conductivity of the connector pad which reduces signal integrity issues due to resonance.

Disclosed herein may be an apparatus and method for detecting ion migration. The apparatus may include: a first printed circuit board (PCB) pad coupled with a ground; a second PCB pad disposed at a position spaced apart from the first PCB pad; a power supply unit configured to supply power to the second PCB pad; a voltage detection unit configured to detect a voltage of an output terminal of the first PCB pad; and a control unit configured to determine whether ion migration has occurred between the first PCB pad and the second PCB pad using the voltage detected by the voltage detection unit.

A manufacturing method of the light-emitting diode package structure is provided. A carrier is formed. The carrier comprises a first build-up circuit. At least one self-assembled material layer is formed on the first build-up circuit. A first solder mask layer is formed on the first build-up circuit. The first solder mask layer has at least one opening to expose a portion of the at least one self-assembled material layer. At least one light-emitting diode is disposed on the first build-up circuit. The at least one light-emitting diode has a self-assembled pattern, and the at least one light-emitting diode is self-assembled into the at least one opening of the first solder mask layer through a force between the self-assembled pattern and the at least one self-assembled material layer.

A ceramic electronic component that includes an electronic component body having a superficial base ceramic layer, a surface electrode on a surface of the electronic component body, and a covering ceramic layer covering a peripheral section of the surface electrode. The peripheral section of the surface electrode that is covered by the covering ceramic layer has an opening or a thin portion.

A light-emitting diode package structure includes a carrier, at least one self-assembled material layer, a first solder mask layer, and at least one light-emitting diode. The carrier includes a first build-up circuit. The self-assembled material layer is disposed on the first build-up circuit. The first solder mask layer is disposed on the first build-up circuit. The first solder mask layer has at least one opening to expose a portion of the self-assembled material layer. The light-emitting diode is disposed on the first build-up circuit. The light-emitting diode has a self-assembled pattern. The light-emitting diode is self-assembled into the opening of the first solder mask layer through a force between the self-assembled pattern and the self-assembled material layer. A manufacturing method of the light-emitting diode package structure is also provided.

Provided is an electronic circuit substrate in which any excess space is not necessary around an electronic component, and position deviation at a time of mounting the electronic component can be prevented with high precision. An electronic circuit substrate 100 includes a printed wiring board 10 and an electronic component 20. The printed wiring board 10 has a first land 11 and a second land 12. The electronic component 20 has a first bond portion 24 which is bonded to the first land 11 with solder, and a second bond portion 25 which is bonded to the second land 12 with solder. The bond area of the first land 11 and the first bond portion 24 is larger than the bond area of the second land 12 and the second bond portion 25. In one direction D1, the position of an outer side edge 24b of the first bond portion 24 is set so as to match the position of the outer side edge 11b of the first land 11.

A fingerprint sensor module includes a fingerprint sensor assembly with a circuit element attached. The fingerprint sensor assembly is electrically connected to a printed circuit board (PCB) substrate with a cutout to accommodate the circuit element. The entire fingerprint sensor assembly and at least part of the PCB are encapsulated in a encapsulating material to produce a structurally robust fingerprint sensor module suitable for integration into an electronics device such as a smartphone or other Internet of Things (IOT) electronic device.

An electronic device is provided. The electronic device includes a display including a display area and a connecting area extending from one side of the display area, a flexible printed circuit board (FPCB) connected with the connecting area, and a first module mounted on a first surface of the FPCB, where the connecting area is bent such that the first module is apart from the display to face the display.

A printed circuit board module (10) has a printed circuit board (20) with a first side (21), a second side (22) and a contact hole (30). A sleeve-type via (32) is provided in the contact hole 30. An annular ring (35, 36) is associated with the via (32), on at least one side (33, 34). The annular ring (35, 36) is arranged on the first side (21) or on the second side (22) of the printed circuit board (20). The annular ring (35, 36) is electrically connected to the via (32). The annular ring (35, 36) has an annular ring edge (40), at least in sections. The printed circuit board module (10) has a solder resist layer (50). It extends, at least in sections, from outside the annular ring edge (40) over the annular ring edge (40) to an outer region (42) of the annular ring (35, 36). An inner region (44) not covered with the solder resist layer (50), remains on the annular ring (35, 36).

Provided is a printed wiring board comprising: a substrate; a conductive layer including a land and a wiring and formed on a surface of the substrate, the wiring having a width smaller than the land and drawn from the land; and an insulating layer formed on the conductive layer. The insulating layer has an opening corresponding to a position of the land, and an edge of the opening runs above the land and above one of edges in a width direction of the wiring.