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 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: An optical waveguide, a package board having the optical waveguide, and manufacturing methods thereof are disclosed. The 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 one side of a first cladding; forming a core between the first reflective bump and the second reflective bump; and stacking a second cladding over the one side of the first cladding such that the second cladding covers the first reflective bump, the second reflective bump, and the core. With this method, inclined surfaces can be formed by stacking a metal layer on the lower cladding and then selectively etching the metal layer, which can reduce lead time and enable a high degree of freedom in design.

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: An optical waveguide, a package board having the optical waveguide, and manufacturing methods thereof are disclosed. The 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 one side of a first cladding; forming a core between the first reflective bump and the second reflective bump; and stacking a second cladding over the one side of the first cladding such that the second cladding covers the first reflective bump, the second reflective bump, and the core. With this method, inclined surfaces can be formed by stacking a metal layer on the lower cladding and then selectively etching the metal layer, which can reduce lead time and enable a high degree of freedom in design.

Abstract: An electromagnetic bandgap structure and a printed circuit board that can solve a mixed signal problem between an analog circuit and a digital circuit are disclosed. In accordance with an embodiment of the present invention, an electromagnetic bandgap structure is stacked with a first metal layer, a first dielectric layer, a metal plate, a second dielectric layer and a second metal layer, and an odd number of vias can be serially connected through a metal line between the first metal layer and the metal plate. This electromagnetic bandgap structure can have a small size and a low bandgap frequency.

Abstract: A parallel chip embedded printed circuit board and manufacturing method thereof are disclosed. With a method of manufacturing a parallel chip embedded printed circuit board, comprising: (a) forming a parallel chip by connecting in parallel a plurality of unit chips having electrodes or electrically connected members formed on the upper and lower surfaces thereof, using at least one conductive member; (b) joining an electrode on one side of the parallel chip to a first board; and (c) joining an electrode on the other side of the parallel chip to a second board, chips may be embedded in a printed circuit board at a low cost, as a plurality of unit chips can be embedded at once, and a mechanical drill or router can be used instead of a laser drill in perforating the cavity or via holes.

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 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 and a method of manufacturing a printed circuit board are disclosed. A printed circuit board in which optical waveguides are formed for transmitting optical signals together with electrical signals, which includes a cladding, a core embedded in the cladding that transmits optical signals, and a wiring pattern embedded in the cladding that transmits electrical signals, can offer improved optical connection efficiency and reduced material costs by enabling the cladding to act as an insulation layer and embedding the wiring pattern in the cladding.

Abstract: An optical printed circuit board which can transfer optical signal and electric signals simultaneously, and a method of fabricating the optical printed circuit board. An optical printed circuit board which includes an upper cladding layer, a core layer positioned in the upper cladding layer that has a first reflecting surface and a second reflecting surface at both ends to guide optical signals, a lower cladding layer of which one side is in contact with the upper cladding layer and which has a circuit pattern and light connecting bumps on the other side corresponding to the first reflecting surface and the second reflecting surface, may provide the advantage of high optical connection efficiency.

Abstract: The alignment marks formed in a scribe line of a semiconductor substrate include at least one main mark, a first sub-mark and second sub-marks. The first sub-mark is formed at a central portion of the main mark. The second sub-marks are disposed symmetrically with respect to the first sub-mark and are used for detecting asymmetry of the main mark by measuring distances between respective side edges of the main mark and the first sub-mark, and by measuring respective side edges between the main mark and each of the second sub-marks. Alternatively, the alignment marks include main outer and inner marks and a sub-mark disposed in between the main outer and inner marks. In this case, the sub-mark is used for detecting asymmetry of the main mark by measuring distances between respective side edges of the main outer mark and the sub-mark, and by measuring respective side edges between the main inner mark and the sub-mark.

Abstract: The present invention relates to a printed circuit board, and in particular, to a printed circuit board for a package of electronic components and manufacturing method thereof. One aspect of present invention provides a manufacturing method of a printed circuit board for an electronic component package, which includes: forming a circuit pattern including bonding pads on one side of a first insulation layer, laminating a second insulation layer onto one side of the first insulation layer, and exposing the bonding pads by removing a part of the first insulation layer and the second insulation layer corresponding to the location in which the bonding pads is formed.

Abstract: A decoding method in a concatenated low-density generator matrix (LDGM) code-based transmission system for detecting a signal using a parity check matrix including a systematic bit part mapped to systematic bits and a parity check part mapped to parity bits. The decoding method includes generating an outer code parity check matrix with a predetermined size using a pseudorandom algorithm; generating an inner code parity check matrix using the outer code parity check matrix; and decoding a received signal using the inner code parity check matrix.

Abstract: Correcting light intensity for photolithography may include irradiating light having a first light intensity distribution through a photo mask having a mask pattern to a photosensitive layer on a wafer to form a first pattern corresponding to the mask pattern. A distribution of critical dimensions of the first pattern corresponding to the mask pattern may be determined, and a second light intensity distribution may be determined based on a relation between the first light intensity distribution and the distribution of critical dimensions of the first pattern. Then, light having the second light intensity distribution may be irradiated. Related systems are also discussed.

Abstract: An apparatus and method for improving decoding performance of a Normalized-BP algorithm in an LDPC-code decoder. The present invention to provides an LDPC-code decoding apparatus, which can be implemented in the form of a simpler configuration than the LLR-BP algorithm, and a method for controlling the same. Further, the present invention provides an LDPC-code decoding apparatus, which improves decoding performance of the Normalized-BP algorithm and at the same time provides similar performance to that of the LLR-BP algorithm, and a method for controlling the same.

Abstract: A method for measuring dimensions of minute structures on a substrate include irradiating primary electrons onto the minute structures, and detecting secondary electrons generated from the minute structures. Image data of the minute structures is formed, and at least two measuring regions are determined over the minute structures using the image data. The dimensions of the minute structures corresponding to the measuring regions are calculated. The primary electrons are provided from an electron emission member to the minute structures, and the secondary electrons are converted into current signals and then imaged in a displaying member. An operation member calculates the dimensions of the minute structures corresponding to the measuring regions using the image data of the minute structures stored in a storage member and measurement data that is measured at the measuring regions.