A wiring board includes an insulating base including a first principal surface, a second principal surface opposite to the first principal surface, and a first through hole penetrating the insulating base from the first principal surface to the second principal surface, a functional material provided inside the first through hole, a first insulating layer covering the first principal surface, and a first surface of the functional material, and a second insulating layer covering the second principal surface, and a second surface of functional material. A second through hole is formed in the first insulating layer, the functional material, and the second insulating layer, and a conductive layer is formed on a wall surface of the second through hole.

The disclosure relates to a method for manufacturing a transfer film including an electrode layer, the method comprising: an electrode layer formation step of forming an electrode layer on a carrier member by using a conductive material; a placement step of placing the carrier member on at least one side of an insulating resin layer respectively; a bonding step of bonding the carrier member and the insulating resin layer together by applying pressure thereto; and a transfer step of removing the carrier member to transfer the electrode layer on the insulating resin layer.

The present invention provides a printed circuit board fabricated by a Non-Plating Process that includes at least one plating bar disposed around at least one package unit of the printed circuit board. The package unit includes at least one ground line, at least one power line and a plurality of signal lines. The ground line has a first contact pad exposed on a surface of the printed circuit board, and at least one of the ground lines is connected to the plating bar. The power line has a second contact pad exposed on the surface, and at least one of the power lines is connected to the neighboring plating bar. The signal line has a third contact pad exposed on the surface.

A method for manufacturing a printed circuit board (PCB) with high component density includes at least two reinforcing plates, at least two connecting plates, a first circuit board unit, and a second circuit board unit. The reinforcing plate includes a supporting portion, a first connecting portion, and a second connecting portion. The first connecting portion and the second connecting portion connect to ends of the supporting portion. The connecting plates are bendable circuit boards. Each connecting plate is attached to the supporting portion, the first connecting portion, and the second connecting portion of a reinforcing plate. The first circuit board unit is fixed and electrically connected to a connecting plate away from first connecting portion. The second circuit board unit is fixed and electrically connected to a connecting plate away from the second connecting portion.

A printed circuit board has a double-sided substrate with an insulation layer, a bonding member, a base layer of an aluminum material, and a circuit pattern; a second insulation layer; a second bonding member; a second base layer; a through hole; a zinc substitution layer; a plating layer; and a second circuit pattern.

The present invention relates to a composition for forming a conductive pattern and a resin structure having a conductive pattern, wherein the composition makes it possible to form a fine conductive pattern on various polymer resin products or resin layers through a simple process, and can more effectively meet needs of the art, such as displaying various colors. The composition for forming a conductive pattern, comprises: a polymer resin; and a non-conductive metal compound having a predetermined chemical structure, and may be a composition for forming a conductive pattern through electromagnetic irradiation, by which a metal nucleus is formed from the non-conductive metal compound.

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 printed wiring board according to as aspect of the present invention includes a base film having insulation properties and a conductive pattern including multiple wiring portions laminated, the conductive pattern running on at least one surface of the base film, wherein each wiring portion includes a first conductive portion and a second conductive portion coating an outer surface of the first conductive portion, wherein an average width of each wiring portion is 10 μm or greater to 50 μm or smaller, and an average thickness of the second conductive portion is 1 μm or greater to smaller than 8.5 μm.

The disclosure provides a circuit substrate and a method for manufacturing the same. The circuit substrate includes a wiring and a substrate having a base region and a circuit region. The base region having a first pattern is constituted by a first thermoplastic material. The circuit region having a second pattern is constituted by a second thermoplastic material. The first pattern has a portion opposite to the second pattern. The wiring is formed on the circuit region along the second pattern. The first thermoplastic material is different from the second thermoplastic material, and the second thermoplastic material includes a catalyst particle.

An autocatalytic gold bath capable of depositing gold from solution onto a substrate, wherein the substrate has one or more metal layers thereon. The autocatalytic gold bath includes (a) a chelator; (b) a gold salt; and (c) a reducing agent, wherein the reducing agent comprises an organic molecule having more than one carbon atom on the organic molecule. A process of plating gold onto the surface of the one or more metal layers on the substrate is also included. The gold plating bath can be used to deposit a final finish to the surface of the one or more metal layers which can be formed in an ENIG, ENEPIG, EPAG, direct gold over copper or gold over silver process.