Abstract: A method of manufacturing a laminate circuit board which includes the sequential steps of metalizing the substrate to form the base layer, forming the first circuit metal layer, forming at least one insulation layer and at least one second circuit metal layer interleaved, removing the substrate, forming the support frame and forming the solder resist is disclosed. The laminate circuit board has a thickness less than 150 ?m. The support frame which does not overlap the first circuit metal layer is formed on the edge of the base layer by the pattern transfer process after the substrate is removed. The base layer formed of at least one metal layer is not completely removed. The support frame provides enhanced physical support for the entire laminate circuit board without influence on the electrical connection of the circuit in the second circuit metal layer, thereby solving the warping problem.

Abstract: A laminate circuit board structure which includes a first circuit metal layer, a first insulation layer, at least one second circuit metal layer, at least one second insulation layer and a support frame is disclosed. The total thickness of the laminate circuit board structure is less than 150 ?m. The support frame provided at the outer edge of the co-plane surface formed by the first circuit metal layer and the first insulation layer does not cover the first circuit metal layer, and is formed of at least one metal material. The support frame provides physical support for the entire board structure without influence on the circuit connection so as to prevent the laminate circuit board structure from warping.

Abstract: A method of thin printed circuit board wet process consistency on the same carrier, and more particularly to a printed circuit board in the developing, copper plating, stripping, etching and other wet processes uses the same frame as a carrier from the beginning to the end of the wet process, such that the thin printed circuit board is conducted a continuous and automatic wet process to avoid disassembly, storage and transportation between each process. Moreover, when using the flame, the thin printed circuit board is smooth and flattening in the wet process for avoiding “water effect,” the effective area is not exposed to any mechanical members for preventing scratches, and there are point contacts between the thin printed circuit board and the frame for preventing chemical residue. Accordingly, the present invention can not only enhance the yield of the thin printed circuit board but also shorten the production time.

Abstract: Disclosed is a final defect inspection system, which including a host device, a microscope, a bar code scanner, a support tool, a signal transceiver and an electromagnetic pen. The bar code scanner scans a bar code on a circuit board provided on the support plate. The host device selects data and a circuit layout diagram from the database corresponding to the bar code. The signal transceiver and the electromagnetic pen are electrically connected to the host device. The electromagnetic pen is used to make a mark on a scrap region of the circuit board where any defect is visually found through the microscope. The signal transceiver receives and transmits the positions of the mark to the host device such that the host device calculates the coordinate of a scrap region based on a relative position between an original point and the positions of the mark.

Abstract: A laminate circuit board with a multi-layer circuit structure which includes a substrate, a first circuit metal layer, a second circuit metal layer, a first nanometer plating layer, a second nanometer plating layer and a cover layer is disclosed. The first circuit metal layer is embedded in the substrate or formed on at least one surface of the substrate which is smooth. The first nanometer plating layer with a smooth surface overlaps the first circuit metal layer. The second nanometer plating layer is formed on the other surface of the substrate and fills up the opening in the cover layer to electrically connect the first circuit metal layer. The junction adhesion is improved by the chemical bonding between the nanometer plating layer and the cover layer/the substrate. Therefore, the circuit metal layer does not need to be roughened and the density of the circuit increases.

Abstract: A method of manufacturing a laminate circuit board with a multilayer circuit structure which includes the steps of forming a metal layer on a substrate, patterning the metal layer to form a circuit metal layer, forming a nanometer plating layer on the circuit metal layer, forming a cover layer to cover the substrate and the nanometer plating layer, forming through holes in the cover layer to generate openings exposing part of the nanometer plating layer, and finally forming a second metal layer on the cover layer to fill up the openings is disclosed. The nanometer plating layer is used to obtain same effect of previously roughening by chemical bonding, such that no circuit width is reserved for compensation, and the density of the circuit increases such that much more dense circuit can be implemented.

Abstract: A high-density fine line structure mainly includes: two boards with similar structures and a dielectric film for combing the two boards. Semiconductor devices respectively in two boards are opposite to each other after the two boards are combined. The two boards each include a fine line circuit, an insulated layer on the same surface, and the semiconductor device installed above the fine line circuit. The surface of the circuit, which is not covered by a solder mask, is made into a pad. The pad is filled with the tin balls for electrically connecting with another semiconductor device. Electroplating rather than the etching method is used for forming the fine line circuit layer, and a carrier and a metal barrier layer, which are needed during or at the end of the manufacturing process, are removed to increase the wiring density for realizing the object of high-density.

Abstract: A manufacturing method of a semiconductor load board is disclosed. The manufacturing method includes a first conductive layer forming step, a first patterning step, a dielectric layer forming step, a drilling step, a second conductive layer forming step, a second patterning step or a two-times patterning step, and a solder connecting step. In a second patterning step or a two-times patterning step, a solder pad is formed in the opening of the dielectric layer, wherein each solder pad has a height higher than the height of the dielectric, and the width of each solder pad is equal to or smaller than the maximum width of the opening, such that wider intervals are provided in the same area and the problems of short circuit failure and electrical interference can be reduced.

Abstract: A solder pad structure with a high bondability to a solder ball is provided. The present invention provides a larger contact area with the solder ball so as to increase the bondability according to the principle that the bondability is positive proportional with the contact area therebetween. The solder pad structure includes a circuit board having a solder pad opening defined by a solder resist layer surrounding a circuit layer. The circuit layer within the solder pad opening is defined as a solder pad. In such a way, after filling the solder ball into the solder pad opening, besides walls of the solder pad opening, there is an extra contact area provided by a geometric shape of the solder pad for further improving the bondability of the solder pad and the solder ball.

Abstract: A method for manufacturing a heat dissipation structure of a printed circuit board includes: forming a barrier layer on the dimple in the first copper plating layer; forming a nickel plating layer; removing the nickel plating layer and the barrier layer on the dimple; forming a second copper plating layer to make the total height of the first copper plating layer and the second copper plating layer in the second opening higher than that of the first copper plating layer in the first opening; filling the dimple in the second copper plating layer with an etching-resistant material; removing the second copper plating layer; removing the nickel plating layer and the etching-resistant material to make the second copper plating layer in the second opening being at the same height as the first copper plating layer in the first opening; and forming the heat dissipation structure by photolithography.

Abstract: Structure and method of making a board having plating though hole (PTH) core layer substrate and stacked multiple layers of blind vias. More stacking layers of blind vias than conventional methods can be achieved. The fabrication method of the board having high-density core layer includes the following: after the making of the PTH, the filling material filled inside the PTH of the core layer is partially removed until the PTH has reached an appropriate flattened depression using etching; then image transfer and pattern plating are performed to fill and to level the depression portion up to a desired thickness to form a copper pad (overplating) as the core layer substrate is forming a circuit layer; finally using electroless copper deposition and the pattern plating to make the product.

Abstract: A method for fabricating an interlayer conducting structure of an embedded circuitry is disclosed. In accordance with the method for fabricating an interlayer conducting structure of an embedded circuitry of the present invention, there is no laser conformal mask formed prior to laminating the first and second lamination plates. Instead, after the first and second lamination plates are laminated, a laser boring process is directly conducted to form a via hole. In such a way, even when there is an offset between the first and the second lamination plates in alignment, the risk of short circuit between different layers of lamination plates can be lowered without improving an interlayer offset value.

Abstract: A method for fabricating a component-embedded PCB includes: providing a carrier plate having a plating metal layer plated thereon; disposing an electronic component on the plating metal layer of the carrier plate; laminating a metal layer onto the plating metal layer having the electronic component disposed thereon and the carrier plate by a dielectric film; removing the carrier plate and exposing the plating metal layer; and patterning at least one of the metal layer and the plating metal layer to be a circuit layer.

Abstract: A manufacturing method for mainly embedding the passive device structure in the printed circuit board is presented. In this structure, both the source electrode and the ground electrode of the passive device belong to the same level, and includes several source branches and several ground branches that are formed vertically on the inside of the dielectric layer of the circuit board which are connected, respectively, to avoid the conducting between the source electrode and the ground electrode during lamination. When it is in the form of the capacitor structure, through the use of the ultra-fine wiring technique, these source branches and ground branches are separated by a small gap between each other. Therefore, the side face area and quantities of the source branches and ground branches are both increased.

Abstract: A circuit board includes a core layer substrate having a plated through hole filled with a dielectric material. The plated through hole has a sidewall coated with an inner electroless copper layer, and an electroplated metal layer plated on the inner electroless copper layer before the plated through hole is filled with the dielectric material. The outer portion of the filled plated through hole is thicker than the center portion and tapered toward the center portion to form a depressed surface on the filled plated through hole. The core layer substrate is covered with a patterned electroless copper layer and a patterned electroplated copper layer that connect with the inner electroless copper layer and electroplated metal layer of the plated through hole. The patterned electroplated copper layer forms a flat copper pad above the plated through hole.

Abstract: A method for fabricating a buried capacitor structure includes: laminating a first dielectric layer having a capacitor embedded therein with a second dielectric layer to bury the capacitor therebetween; forming a first circuit pattern on a first metal layer of the first dielectric layer and a second circuit pattern on a second metal layer of the second dielectric layer; depositing a first insulating layer and a second insulating layer on the first metal layer and the second metal layer, respectively; electrically connecting a positive electrode end and a negative electrode end of the capacitor to the second metal layer by a positive through-hole and a negative through-hole, thereby manufacturing the buried capacitor structure.

Abstract: A method for selectively processing a surface tension of a solder mask layer in a circuit board is provided. The method conducts surface tension processing to the flip-chip area and the non-flip-chip area of the solder mask layer in the circuit board. Therefore, the underfill used in packaging configures relative contact angles at the flip-chip area and the non-flip-chip area of the solder mask layer, respectively. In such a way, the present invention is adapted to solve the difficulties of the underfill void bulb and the overflowing contamination at the same time.

Abstract: A manufacturing method of a non-etched circuit board is disclosed herein, which employs a metal substrate having a metal barrier layer and an electroplated copper layer to transmit an electrical current to form a circuit layer. A patterned photoresist layer is formed on the electroplated copper layer to define the location of the circuit layer and form circuits or conductive via on the board by electroplating. An electroplated nickel layer or an electroplated gold layer is further formed on the circuit layer for protecting the circuits and improving the fine line capability. During or after the process, the metal substrate, the metal barrier layer, and the electroplated copper layer are removed to enlarge the wiring space, so that a high-density circuit board can be obtained.

Abstract: A package structure preventing solder overflow on substrate solder pads includes a plurality of die pins, a plurality of solders and a plurality of substrate solder pads. The die pins are located under a die. The substrate solder pads are formed on an upper surface of a substrate by copper plating or etching. Each of the substrate solder pads has at least one solder pad connection point. The solders connect the die pins with the corresponding solder pad connection points, respectively. Each of the solder pad connection points has a pair of solder pad ridges or a pair of solder pad grooves. The solder pad ridges and the solder pad grooves filled with the solder or a resin can prevent the solder overflow problem.

Abstract: A carrier substrate and a method for manufacturing the carrier substrate are disclosed herein. The method includes the steps of: providing a core substrate; forming a build-up material layer on the core substrate; forming a via in the build-up material layer; forming a patterned photoresist layer on the build-up material layer covering a portion of the via and exposing an opening from uncovered portion of the via, and a wiring slot connected to the opening; and forming a metal-electroplated layer on the via and the wiring slot. In forming a trace according to the present invention, the metal-electroplated layer is formed as the trace and directly connected to the via, striding or not striding over the via. Additionally, in the carrier substrate structure, there is no need an annular ring to connect the trace to the via, and thus the wiring space is increased.