A package that includes a substrate and an electrical component coupled to the substrate. The substrate includes at least one dielectric layer, a plurality of interconnects located in the at least one dielectric layer, and a solder resist layer located over a surface of the at least one dielectric layer. The solder resist layer includes a first solder resist layer portion comprising a first thickness, and a second solder resist layer portion comprising a second thickness that is less than the first thickness. The electrical component is located over the second solder resist layer portion.

A process for efficiently producing a wiring board in which an insulating substrate 1 having a through hole 2 is used, which includes forming a seed layer 3 on one surface of the insulating substrate 1, covering the surface of the insulating substrate 1 on which the seed layer 3 is formed with a masking film 4, arranging the insulating substrate 1 and a positive electrode 5 so that the surface of the insulating substrate 1 opposite to the surface of the insulating substrate 1 on which the seed layer 3 of the insulating substrate 1 is formed is faced to the positive electrode 5, carrying out electroplating to form a metal layer 8 in the through hole 2, and then removing the masking film 4.

The invention eliminates defects generated in a metal filling a through hole of a printed board by changing an angle at which a plating solution is sprayed or by changing a posture of the printed board at a time point in a process of precipitating the metal from the plating solution and filling the through hole with the precipitated metal while the plating solution or air bubbles are being sprayed onto the printed board.

A printed circuit board with embedded component includes a double-sided printed circuit board, an electronic component, a plurality of conductive paste blocks, an insulating layer and a wiring layer near the first wiring layer, an insulating layer and a wiring layer near the second wiring layer. The double-sided printed circuit board comprising a first wiring layer, a base, and a second wiring layer. The first wiring layer and the second wiring layer are arranged on opposite sides of the base. The second wiring layer includes a plurality of electrical contact pads. The base defines a number of conductive vias. Each electrical contact pad is aligned with and electrically connected to one corresponding conductive via. The conductive paste blocks are electrically connecting to the conductive vias. The electronic component is electrically connected to the conductive paste blocks. The two insulating layers cover the electronic component and the second wiring layer.

A component carrier includes a layer stack formed of an electrically insulating structure and an electrically conductive structure with a bore extending into the layer stack. The bore includes a first bore section with a first diameter and a connected second bore section with a second diameter differing from the first diameter. The component carrier further comprises a thermally conductive material filling substantially the entire bore. The bore is in particular formed by mechanical drilling.

A wiring substrate is provided with a surface wiring on at least one surface, a through hole which passes through the wiring substrate, and a through wiring which is formed in the through hole and is connected to a surface wiring, in which an inner surface of the through hole is a rough surface, and electric resistance of the through wiring is equal to or less than the electric resistance of the surface wiring.

Disclosed is a structure of a flexible circuit board combined with a carrier board. The carrier board includes a thick copper layer, a thin copper layer, and a release layer formed between the thick copper layer and the thin copper layer. The flexible circuit substrate and the carrier board are bonded together by an adhesive layer. In a subsequent process, the release layer, together with the thick copper layer, is peeled from a top surface of the thin copper layer and the thin copper layer is preserved by being bonded by the adhesive layer to the flexible circuit substrate.

Pastes are disclosed that are configured to coat a passage of a substrate. When the paste is sintered, the paste becomes electrically conductive so as to transmit electrical signals from a first end of the passage to a second end of the passage that is opposite the first end of the passage. The metallized paste contains a lead-free glass frit, and has a coefficient of thermal expansion sufficiently matched to the substrate so as to avoid cracking of the sintered paste, the substrate, or both, during sintering.

A printed wiring board includes first, second, and third wiring layers, first and second insulating members, and first and second vias. The first wiring layer includes a recognition mark and a first wiring on a first surface. The second wiring layer includes a first pad and a second wiring. The third wiring layer includes a third wiring. The first via penetrates the first insulating member and electrically connects the recognition mark to the first pad. The second via penetrates the second insulating member and electrically connects the first pad to the third wiring. The first pad and the first and second vias are in a region within an outer perimeter of the recognition mark when viewed from a direction orthogonal to the first surface.

A three-dimensional (3D) metal object manufacturing apparatus selects operational parameters for operation of the printer to form vias in substrates. The apparatus identifies the bulk metal being melted for ejection and uses this identification data to select the operational parameters. The apparatus identifies the via holes in the substrate and positions an ejector opposite the via holes to eject drops of melted bulk metal toward the via holes to fill the via holes.