Abstract: A printed circuit board and a method of manufacturing the printed circuit board are disclosed. The method of manufacturing the printed circuit board can include forming a first protective layer over one surface of a core substrate, forming a first circuit pattern over the other surface of the core substrate by a first process, removing the first protective layer, forming a second protective layer over the other surface of the core substrate, and forming a second circuit pattern over the one surface of the core substrate by a second process.

Abstract: Disclosed herein is a printed circuit board for an optical waveguide, including a base board, and an optical waveguide formed on the base board. The optical waveguide includes a lower clad layer formed on the base board, an insulation layer formed on the lower clad layer and having a core-forming through-hole, a core part formed on a region of the lower clad layer, which is exposed through the through-hole, and an upper clad layer formed in the through-hole and on the insulation layer.

Abstract: A printed circuit board is disclosed. The printed circuit board includes a first board unit and a second board unit disposed with a gap in-between, and a flexible optical board configured to transmit optical signals, which has one side stacked on the first board unit and the other side stacked on the second board unit, where the flexible optical board includes a core through which the optical signals travel, a cladding surrounding the core, and a circuit pattern buried in the cladding which transmits electrical signals. By forming the rigid boards and the flexible optical board as an integrated structure, the need for separate connectors is obviated, and thus the cost of the product can be lowered.

Abstract: A method of manufacturing a printed circuit board for optical waveguides, including: preparing a base substrate; forming an optical waveguide, which includes a lower clad, a core formed on an upper middle of the lower clad, and an upper clad formed on the lower clad to surround an upper surface and a side surface of the core, on an upper middle of the base substrate; disposing a side substrate including a first side substrate that has a through hole, through which the optical waveguide penetrates, provided at the middle thereof and a first circuit pattern formed therein and a second side substrate disposed on the first side substrate on the upper part of the base substrate on which the optical waveguide is formed; disposing an upper substrate on the side substrate on which the through hole is formed; and stacking the side substrate and the upper substrate on the base substrate on which the optical waveguide is formed.

Abstract: The present invention provides an optical flexible printed circuit board comprising: a base layer; an optical waveguide pattern disposed on a partial region of the base layer; an insulating layer which is disposed on the base layer with the optical waveguide pattern and has a surface profile bent by the optical waveguide pattern; and circuit wires disposed on one surface of the base layer.

Abstract: A method of fabricating a printed circuit board is disclosed. A method of fabricating a printed circuit board that includes: stacking an insulation layer on at least one surface of a core layer, on which an inner circuit is formed, and forming an outer circuit pattern; burying the outer circuit pattern in the insulation layer; removing the outer circuit pattern to form minute grooves and curing the insulation layer; and forming an outer circuit by filling metal in the minute grooves, makes it possible to readily form high-resolution fine-line circuits, as well as to reduce fabrication costs and increase productivity.

Abstract: A printed circuit board is disclosed. A printed circuit board, which includes a first board part, a flexible board part which has one side coupled with the first board part and which includes an electrical wiring layer and an optical waveguide to transmit both electrical signals and optical signals, and a second board part coupled with the other side of the flexible board part, where the electrical wiring layer and the optical waveguide are disposed with a gap in-between, can provide greater bendability and reliability, by having the optical waveguide and electrical wiring layer separated with a gap in-between at the flexible portion of the board, and the optical waveguide can be manufactured with greater precision for even higher reliability, by having the optical waveguide manufactured separately and then inserted during the manufacturing process of the board.

Abstract: A method of manufacturing an optical waveguide includes: forming a first reflective bump and a second reflective bump, which have inclined surfaces formed on sides opposite to each other and which are disposed with a predetermined distance in-between, on an upper side of a conductive carrier; polishing the surfaces of the first reflective bump and the second reflective bump; forming a core between the first reflective bump and the second reflective bump; stacking an upper cladding over the upper side of the carrier to cover the first reflective bump, the second reflective bump, and the core; removing the carrier; and stacking a lower cladding over a lower side of the upper cladding. Forming reflective bumps on a conductive carrier, and polishing the reflective bumps to form inclined surfaces, can reduce lead time and can provide a high degree of freedom in design.

Abstract: The present invention relates to a printed circuit board for optical waveguides and a method of manufacturing the same. The present invention provides a printed circuit board for optical waveguides includes: a base substrate; an optical waveguide that is formed on an upper middle of the base substrate and includes a lower clad, a core formed on an upper middle of the lower clad, and an upper clad formed on the lower clad to surround an upper surface and a side surface of the core; and a side substrate that is formed on the base substrate and has a through hole, through which the optical waveguide penetrates, provided at the middle thereof and a circuit pattern formed therein and a method of manufacturing a printed circuit board for optical waveguides.

Abstract: A printed circuit board including a first optical waveguide having a circuit pattern and a pad buried in one side thereof, a first insulation layer stacked over one side of the first optical waveguide, a first insulating material stacked over the first insulation layer, a first electrical wiring layer stacked over the first insulating material, a second optical waveguide having a circuit pattern and a pad buried in one side thereof, a second insulation layer stacked over one side of the second optical waveguide, a second insulating material stacked over the second insulation layer, a second electrical wiring layer stacked over the second insulating material, an intermediate layer interposed between the other side of the first optical waveguide and the other side of the second optical waveguide such that the first optical waveguide and the second optical waveguide are attached, and a via penetrating the first optical waveguide and the second optical waveguide.

Abstract: A method of manufacturing an optical waveguide is disclosed. The method in accordance with an embodiment of the present invention includes providing a carrier, fixing a base substrate to the carrier by using a first insulation layer such that the base substrate is directly stacked on the carrier, stacking an optical waveguide layer on at least one of the base substrate and the first insulation layer, and severing the base substrate such that the base substrate and the optical waveguide layer are separated from the carrier. Accordingly, the optical waveguide layer can be formed with a uniform thickness since wrinkles in the base substrate supporting the optical waveguide layer are prevented from forming during the manufacturing process.

Abstract: An optical wiring board and a manufacturing method thereof are disclosed. In accordance with an embodiment of the present invention, the method includes providing a base substrate having an optical waveguide layer with a mirror groove formed on one surface thereof and a first insulation layer stacked on one surface of the optical waveguide layer and having a through-hole connected with the mirror groove formed thereon, forming a metal mirror layer connected from the mirror groove to an inner wall of the through-hole and forming an electrode pad on a side of the other surface of the optical waveguide layer, in which the electrode pad is disposed in accordance with the position of the metal mirror layer.

Abstract: An optical wiring board and a manufacturing method thereof are disclosed. In accordance with an embodiment of the present invention, the method includes providing a flexible optical waveguide layer, selectively forming a reinforcing clad on one surface of the optical waveguide layer and forming a mirror groove on the other surface of the optical waveguide layer in accordance with where the reinforcing clad is formed. Thus, the clad can be formed thick only on the place where the mirror groove is to be formed, and thus a flexible optical wiring board having flexibility can be manufactured even though the optical wiring board is generally made thin.

Abstract: An optical wiring board and a manufacturing method thereof are disclosed. In accordance with an embodiment of the present invention, the method includes providing a base substrate having a wiring groove formed therein, forming a first clad layer by filling a first clad substance in the wiring groove, stacking an intermediate insulating layer on the base substrate, in which the intermediate insulating layer has a through-hole formed therein and the through-hole corresponds to the wiring groove, forming a core unit on the first clad layer, forming a second clad layer by filling a second clad substance in the through-hole, in which the second clad layer covers the core unit, and stacking a cover insulting layer on the intermediate insulating layer, in which the cover insulating layer covers the second clad layer.

Abstract: An optical wiring board and a manufacturing method thereof are disclosed. In accordance with an embodiment of the present invention, the method includes providing a base substrate having a wiring groove formed therein, forming a first clad layer by filling a first clad substance in the wiring groove, stacking an intermediate insulating layer on the base substrate, in which the intermediate insulating layer has a first through-hole formed therein and the first through-hole corresponds to the wiring groove, forming a core unit on the first clad layer, stacking a cover insulting layer on the intermediate insulating layer, in which the cover insulating layer has a second through-hole formed therein and the second through-hole corresponds to the first through-hole, and forming a second clad layer by filling a second clad substance in the second through-hole, in which the second clad layer covers the core unit.

Abstract: An optical wiring board having a core, the optical wiring board including: a lower cladding; a side cladding formed over the lower cladding and having an indentation formed therein, the indentation being in correspondence with the core; a core embedded in the indentation; and an upper cladding covering the core, wherein a height of the core is different from a depth of the indentation

Abstract: The present invention relates to a printed circuit board for optical waveguides and a method of manufacturing the same. The present invention provides a printed circuit board for optical waveguides includes: a base substrate; an optical waveguide that is formed on an upper middle of the base substrate and includes a lower clad, a core formed on an upper middle of the lower clad, and an upper clad formed on the lower clad to surround an upper surface and a side surface of the core; and a side substrate that is formed on the base substrate and has a through hole, through which the optical waveguide penetrates, provided at the middle thereof and a circuit pattern formed therein and a method of manufacturing a printed circuit board for optical waveguides.

Abstract: A printed circuit board including a first optical waveguide having a circuit pattern and a pad buried in one side thereof, a first insulation layer stacked over one side of the first optical waveguide, a first insulating material stacked over the first insulation layer, a first electrical wiring layer stacked over the first insulating material, a second optical waveguide having a circuit pattern and a pad buried in one side thereof, a second insulation layer stacked over one side of the second optical waveguide, a second insulating material stacked over the second insulation layer, a second electrical wiring layer stacked over the second insulating material, an intermediate layer interposed between the other side of the first optical waveguide and the other side of the second optical waveguide such that the first optical waveguide and the second optical waveguide are attached, and a via penetrating the first optical waveguide and the second optical waveguide.

Abstract: Disclosed herein is a printed circuit board for an optical waveguide, including: a lower substrate; an insulation layer which has a through-hole and is formed on the lower substrate; an optical waveguide which is formed in the through-hole such that a clearance is present between the optical wave guide and an inner wall of the through-hole; and an adhesive material which is charged in the clearance. The printed circuit board for an optical waveguide is advantageous in that a lower clad material, a core material and an upper clad material are sequentially applied on the lower substrate partially, not entirely, based on the region in which a core is formed, and is then patterned to form an optical waveguide, so that the amounts of the lower and upper clad materials and the core material, which are used to form the optical waveguide, can be greatly decreased.

Abstract: Disclosed herein is an optical element package substrate configured such that electric wiring substrates having a cavity are layered on both sides of an optical waveguide, an optical element package is mounted in the electric wiring substrates, and an optical element mounted on the surface of the optical element package is housed in the cavity, so that the distance between the optical element and the optical waveguide is decreased, thereby increasing optical connection efficiency.