A method for manufacturing a flexible printed circuit board includes having a base layer, and creating a pattern line and at least one conductive pole. The base layer defines at least one communication hole penetrating through the base layer. The pattern line includes two conductive circuit layers formed on opposite surfaces of the base layer. The at least one conductive pole is formed in the at least one communication hole and electrically connects the two conductive circuit layers. A diameter of each conductive pole is less than a diameter of a communication hole.

A printed circuit board includes a substrate including a plurality of wiring layers; a first metal post disposed on the substrate and connected to at least a portion of an uppermost wiring layer among the plurality of wiring layers; a second metal post disposed on the substrate and connected to at least another portion of the uppermost wiring layer among the plurality of wiring layers; a resist layer disposed on the substrate and embedding at least a portion of each of the first and second metal posts; and a metal via penetrating through the resist layer on the second metal post and connected to the second metal post.

A manufacturing method of a double layer circuit board comprises forming a connecting pillar on a first circuit, wherein the connecting pillar comprises a first end, connected to the first circuit, and a second end, opposite to the first end; forming a substrate on the first circuit and the connecting pillar; drilling the substrate to expose a portion of the second end of the connecting pillar, wherein the other portion of the second end of the connecting pillar is covered by the substrate; and forming a second circuit on the substrate and the portion of the second end of the connecting pillar, wherein an area of the first end connected to the first circuit layer is greater than an area of the portion of the second end connected to the second circuit layer.

A method for manufacturing a printed wiring board includes forming metal posts on a conductor circuit formed on a resin insulating layer, forming the outermost resin layer on the resin insulating layer such that the metal posts is embedded in the outermost resin layer, forming a mask at a dam formation site for a dam structure of the outermost resin layer to surround at least part of a pad group including the metal posts on the outermost resin layer, and reducing a thickness of the outermost resin layer exposed from the mask such that end portions of the metal posts are exposed from the outermost resin layer, that the metal posts form the pad group, and that the outermost resin layer has the dam structure forming part of the outermost resin layer and formed to surround at least part of the pad group including the metal posts.

In a wiring base body of a printed wiring board, a conductive post including a wiring portion and a wiring are embedded in an insulating resin film. Therefore, even in a region in which a wiring portion is formed, the wiring base body is not increased in thickness. In addition, even in a region in which a wiring is formed, the wiring base body is not increased in thickness. Therefore, it is possible to obtain a printed wiring board having high flatness by stacking a plurality of wiring base bodies and constituting a printed wiring board.

In a printed wiring board, when a plurality of wiring base bodies are collectively stacked, a constituent material of a first layer of an insulating resin film has a low melting point, so that the first layer is easily melted. Therefore, thermal welding on an upper surface of the wiring base body is reliably performed, and the wiring base bodies are bonded to each other with high reliability.

An apparatus system is provided which comprises: a substrate; a metal pillar formed on the substrate, the metal pillar comprising a first section and a second section, wherein the first section of the metal pillar is formed by depositing metal in a first opening of a first photoresist layer, and wherein the second section of the metal pillar is formed by depositing metal in a second opening of a second photoresist layer.

A chip socket defined by an organic matrix framework, wherein the organic matrix framework comprises at least one via post layer where at least one via through the framework around the socket includes at least one capacitor comprising a lower electrode, a dielectric layer and an upper electrode in contact with the via post.

Provided is a double layer circuit board and a manufacturing method thereof. The double layer circuit board comprises a substrate, a first circuit layer formed on a first surface of the substrate, a second circuit layer formed on a second surface of the substrate, and at least one connecting pillar formed in and covered by the substrate. Each one of the at least one connecting pillar includes a first end connected to the first circuit layer and a second end connected to the second circuit layer. A terminal area of the second end is greater than a terminal area of the first end. Therefore, the second circuit layer is firmly connected to the first circuit layer through the at least one connecting pillar. A yield rate of the double layer circuit board may be increased.

A manufacturing method of a double layer circuit board comprises forming at least one connecting pillar on a first circuit, wherein the at least one connecting pillar comprises a first end, connected to the first circuit, and a second end, opposite to the first end; forming a substrate on the first circuit and the at least one connecting pillar; drilling the substrate to expose a portion of the second end of the at least one connecting pillar, wherein the other portion of the second end of the at least one connecting pillar is covered by the substrate; and forming a second circuit on the substrate and the portion of the second end of the at least one connecting pillar, wherein an area of the first end connected to the first circuit layer is greater than an area of the portion of the second end connected to the second circuit layer.