A substrate includes a base layer, first and second circuit layers both coupled to the base layer, a third circuit layer, a fourth circuit layer and two solder resist layers. The first/second circuit layer defines a first/second opening. The third and fourth circuit layers are located at two sides of the first and second circuit layers. The solder resist layers cover outer faces of the third and fourth circuit layers. Each solder resist layer defines a window. The first opening is deviated from the second opening. The third and fourth circuit layers each have a portion exposed to the window to be a solder pad. The first circuit layer and the third circuit layer have a total thickness no more than that of the second circuit layer and the fourth circuit layer. A chip package with the substrate and a method for manufacturing the substrate are also provided.

The present invention refers to a method of preparing a high density interconnect printed circuit board (HDI PCB) or IC substrates including through-holes and/or grate structures filled with copper, which comprises the steps of: a) providing a multi-layer substrate; b) forming a non-copper conductive layer or a copper layer on the cover layer and on an inner surface of the through-hole, respectively on an inner surface of the grate structure; c) forming a patterned masking film; d) electrodepositing copper; e) removing the masking film; and f) electrodepositing a copper filling.

A manufacturing method for a component incorporated substrate according to the present invention includes positioning an electronic component with reference to a mark formed on a copper layer, the mark consisting of a material less easily etched than copper by a copper etching agent used for etching of copper, after mounting the electronic component on the copper layer with an adhesive layer interposed therebetween, embedding the electronic component and the mark in an insulating substrate, thereafter, etching and removing a part of the copper layer to form a window for exposing the mark, forming an LVH reaching a terminal of the electronic component with reference to the exposed mark, electrically connecting the terminal and the copper layer via a conduction via formed by applying copper plating to the LVH, and, thereafter, forming the copper layer into a wiring pattern.

The present publication discloses a method for manufacturing a circuit-board structure. In the method, a conductor layer is made, which comprises a conductor foil and a conductor pattern on the surface of the conductor foil. A component is attached to the conductor layer and the conductor layer is thinned, in such a way that the conductor material of the conductor layer is removed from outside the conductor pattern.

Provided is a method of manufacturing a printed circuit board, the method including: preparing an insulating substrate including a resin material in which a solid component is impregnated; forming a circuit pattern groove on the resin material by etching an upper surface of the insulating substrate; forming a plated layer in which the circuit pattern groove is buried; and forming a buried circuit pattern by removing the plated layer until the insulating layer is exposed, wherein the solid component has a diameter of less than 5% to a width of the buried circuit pattern. Thus, as a filler of a predetermined size or less is applied into the insulating layer for forming the circuit pattern, the occurrence of a void due to separation of the filler from a boundary part with the circuit pattern can be reduced, and reliability can be also secured.

A printed wiring board includes an uppermost insulating layer, first pads positioned to mount an IC chip on the insulating layer, second pads positioned to mount a second printed wiring board on the insulating layer, metal posts formed on the second pads, respectively, such that the metal posts mount the second board over the chip, and a solder resist layer formed on the uppermost insulating layer and having first and second openings such that the first openings exposes the first pads and that the second openings exposes the second pads, respectively. The metal posts are formed such that each of the metal posts has a diameter which is smaller than a diameter of each of the second opening portions, and the second opening portions are formed such that the diameter of each of the second opening portions is smaller than a diameter of each of the second pads.

Provided are a printed circuit board and a method of manufacturing the same, the printed circuit board according to the present invention, the printed circuit board, including: an insulating substrate having a plurality of circuit pattern grooves formed on a surface thereof; and a plurality of circuit patterns formed by burying the circuit pattern grooves, wherein the circuit patterns protrude as much as a predetermined thickness from an upper surface of the insulating substrate.

A micro circuit structure includes a circuit substrate, a circuit pattern layer, and a fixed layer. A first surface of the circuit substrate has a plurality of recessed portions. The circuit pattern layer is formed on the first surface of the circuit substrate. The circuit pattern layer includes a plurality of circuit patterns, a gap between the circuit patterns is less than 10 m, and each of the circuit patterns is located between two recessed portions. The fixed layer is formed on the first surface of the circuit substrate and between the circuit patterns, where a second surface of the circuit pattern is exposed to a third surface of the fixed layer. By arranging the recessed portions between the circuit patterns, residual metal substances can be removed to avoid a short circuit caused by conduction, and a problem of electron-migration.

The present invention refers to a method of preparing a high density interconnect printed circuit board (HDI PCB) or IC substrates including through-holes and/or grate structures filled with copper, which comprises the steps of: a) providing a multi-layer substrate; b) forming a non-copper conductive layer or a copper layer on the cover layer and on an inner surface of the through-hole, respectively on an inner surface of the grate structure; c) forming a patterned masking film; d) electrodepositing copper; e) removing the masking film; and f) electrodepositing a copper filling.

Disclosed are an ultra-thin copper foil with a carrier foil and a method for manufacturing an embedded substrate by using the same, the ultra-thin copper foil with a carrier foil including: a carrier foil; a non-etching release layer on the carrier foil; a first ultra-thin copper foil layer on the non-etching release layer; an etch stop layer on the first ultra-thin copper foil layer; and a second ultra-thin copper foil layer on the etch stop layer.