A printed circuit board (PCB) having a reliable electrical connection with connection terminals and a semiconductor package including the PCB, the printed circuit board including: a substrate base; a plurality of pads disposed on upper and lower surfaces of the substrate base; and a solder resist layer configured to cover at least a portion of the upper and lower surfaces of the substrate base, wherein at least some of the plurality of pads are groove pads comprising at least one annular groove in a side opposite to the substrate base.

Systems and techniques are provided for trench cutting with laser machining. A laminate material including a conductive layer and a non-conductive layer may be cut with a first cut using a UV-laser. The cutting of a second cut, using the UV-laser, may be started at a top electrode of the non-conductive layer based on the location of the first cut, wherein the second cut is wider than the first cut. The cutting of the second cut may be stopped partially though the non-conductive layer. The stopping of the cutting of the second cut partially though the non-conductive layer may include stopping the cutting of the second cut before cutting a bottom electrode of the non-conductive layer.

A printed circuit board includes a plurality of layers including attachment layers and routing layers; and columns of via patterns formed in the plurality of layers, wherein via patterns in adjacent columns are offset in a direction of the columns, each of the via patterns comprising: first and second signal vias forming a differential signal pair, the first and second signal vias extending through at least the attachment layers; and at least one conductive shadow via located between the first and second signal vias of the differential pair. In some embodiments, at least one conductive shadow via is electrically connected to a conductive surface film.

A semi-finished product for the production of a printed circuit board having a plurality of alternately arranged insulating layers and conductive layers and at least one hard gold-plated edge connector is characterized by the hard gold-plated edge connector being arranged on an inner conductive layer of the semi-finished product and being fully covered by at least one group of an insulating layer and a conductive layer. The inventive Method for producing a printed circuit board having a plurality of alternately arranged insulating layers and conductive layers and at least one hard gold-plated edge connector, where an outer conductive layer is surface treated, is characterized by the steps of providing a hard gold-plated edge connector on a group of an insulating layer and a conductive layer, covering the conductive layer and the hard gold-plated edge connector with at least one group of an insulating layer and a conductive layer, surface-treating an outer conductive layer to form connector pads for wire bonding of electronic components, cutting the insulating layers and the conductive layers down to the conductive layer forming the hard gold-plated edge connector, removing the insulating layers and conductive layers from the hard gold-plated edge connector. The inventive printed circuit board comprised of a plurality of alternately arranged insulating layers and conductive layers and at least one hard gold-plated edge connector is characterized by the hard gold-plated edge connector being arranged on an inner conductive layer of the printed circuit board, and the inner conductive layer forming the hard gold-plated edge connector protruding from the plurality of insulating layers and conductive layers.

The present invention relates to printed circuit boards (PCBs), and more particularly, to methods of forming high aspect ratio through holes and high precision stub removal in a printed circuit board (PCB). The high precision stub removal processes may be utilized in removing long stubs and short stubs. In the methods, multiple holes of varying diameter and depth are drilled from an upper and/or lower surface of the printed circuit board utilizing drills of different diameters.

A wiring board includes: a base material including, on one side of the base material, a protruding part that protrudes toward an outside, wherein the protruding part has a shape in which a center portion of a principal surface rises from the outer periphery, and a plurality of external connection terminals is arranged on the principal surface. A composite substrate includes: the above-mentioned wiring board and a metallic frame member, wherein the frame member includes an opening whose shape is corresponding to a shape in a plan view of the protruding part, and the frame member is arranged such that the opening surrounds the protruding part to fill a periphery of the protruding part. An electric device includes: an electric element on a right face of the wiring board.

Disclosed are a package structure of an integrated passive device and a manufacturing method thereof and a substrate. The method includes: providing an organic frame having a chip embedding cavity and a metal pillar, laminating at least one layer of first dielectric on an upper surface of the organic frame, and processing the first dielectric by photolithography to form an opening correspondingly above the chip embedding cavity; mounting an electronic component in the chip embedding cavity through the opening, the electronic component including an upper and lower electrodes; laminating and curing a second dielectric into the chip embedding cavity and on an upper surface of the first dielectric, thinning the first and second dielectrics to expose the upper and lower electrodes, upper and lower surfaces of the metal pillar; performing metal electroplating to form a circuit layer communicated with the upper and lower electrodes and the metal pillar.

An electronic device according to various embodiments comprises: a circuit element; a printed circuit board comprising a first connection pad connected to the ground of the electronic device, a second connection pad, and a third connection pad arranged between the first connection pad and the second connection pad and connected to a signal terminal of the circuit element; and a flexible printed circuit board (FPCB) comprising a coupling part connected to the printed circuit board, and a connection part extending from the coupling part, wherein the FPCB comprises first ground wiring connected to the first connection pad and extending from the coupling part to the connection part in an assigned direction, second ground wiring connected to the second connection pad and extending from the coupling part to the connection part in the assigned direction, signal wiring connected to the third connection pad and extending from the coupling part to the connection part in the assigned direction, while being arranged between the first ground wiring and the second ground wiring, and third ground wiring arranged in an opposite direction to the assigned direction so as to be connected, in the coupling part, to the first ground wiring and the second ground wiring and surround the signal wiring. Other various embodiments are possible.

The present disclosure relates to a printed circuit board assembly including a first circuit board including a first footprint, the first circuit board further includes a plurality of first vertical vias extending between a first side and an opposing second side; a second circuit board including a second footprint smaller than the first footprint, the second circuit board further includes a plurality of second vertical vias extending between a subsequent first side and an opposing subsequent second side; an adhesive layer coupling the first side to the subsequent first side; and a plurality of third vertical vias extending through the first side and the subsequent first side.

Disclosed herein is an antenna device that includes: a substrate having a plurality of insulating layers laminated in a z-direction; a first ground pattern formed on a first insulating layer; a first radiating conductor pattern formed on a second insulating layer; a second ground pattern constituted by a first via conductor provided so as to penetrate at least two insulating layers; and a second radiating conductor pattern constituted by a second via conductor provided so as to penetrate at least one insulating layer. The first radiating conductor pattern overlaps the first ground pattern in the z-direction. The second radiating conductor pattern overlaps the second ground pattern in a y-direction.