Abstract: A stacked multilayer structure, including a first circuit layer having bumps, a plastic film stacked on the first circuit layer to fill up the space among the bumps so as to form a co-plane, and a second circuit layer formed on the co-plane and connected to the first circuit layer. The plastic film includes a glass fiber layer which is embedded and not exposed.

Abstract: A package structure includes a thin chip substrate, a stabilizing material layer, a chip and a filling material. A first circuit metal layer of the substrate is inlaid into a dielectric layer and a co-plane is defined by the first circuit metal layer and the dielectric layer and is exposed from the dielectric layer. The bonding pads of the substrate are on the co-plane, have a height higher than the co-plane and connected to the first circuit metal layer. The stabilizing material layer is provided on two sides of the co-plane to define a receiving space for accommodating the chip. The filling material is injected into the receiving space to fasten the pins of the chip securely with bonding pads. Since no plastic molding is required, a total thickness of the package structure and the cost is reduced. The stabilizing material layer prevents the substrate from warping and distortion.

Abstract: A compound carrier board structure of Flip-Chip Chip-Scale Package and manufacturing method thereof provides a baseplate having a flip region with a through-opening and bonding to a Non-conductive Film to bond to a carrier board in order to form a compound carrier board structure. Therefore, when a die is planted in the film region of the carrier board structure, the carrier board is able to susceptible to different stresses during a package process. The baseplate uses the low Thermal Expansion Coefficient material to avoid warpage problems caused by the thermal expansion of the carrier board resulting from the thermal stresses. The carrier board is able to disperse conduction of thermal stresses by the baseplate in order to strengthen cooling effect of the compound carrier board structure. Thus, the present invention achieves miniaturization and heat strengthening and enhances the mechanical strength.

Abstract: A method of manufacturing a chip support board structure which includes the steps of forming a metal substrate structure, forming a photo resist pattern, etching the metal substrate structure to form a paddle, removing the photo resist pattern, pressing an insulation layer against the paddle, polishing the insulation layer, forming a circuit layer and forming a solder resist is disclosed. The metal substrate structure is formed by sandwiching a block layer with two metal substrate layers, multilayer. The metal substrate structure is etched under control to an effective depth such that each paddle thus formed has the same shape and depth. Therefore, the method of the present invention can be widely applied to the general mass production processes to effectively solve the problems in the prior arts due to depth differences, such offset, position mismatch and peeling off in the chip support board.

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 package structure includes a thin chip substrate, a stabilizing material layer, a chip and a filling material. A first circuit metal layer of the substrate is inlaid into a dielectric layer and a co-plane is defined by the first circuit metal layer and the dielectric layer and is exposed from the dielectric layer. The bonding pads of the substrate are on the co-plane, have a height higher than the co-plane and connected to the first circuit metal layer. The stabilizing material layer is provided on two sides of the co-plane to define a receiving space for accommodating the chip. The filling material is injected into the receiving space to fasten the pins of the chip securely with bonding pads. Since no plastic molding is required, a total thickness of the package structure and the cost is reduced. The stabilizing material layer prevents the substrate from warping and distortion.

Abstract: Disclosed is a method of manufacturing a stacked multilayer structure, including the steps of forming a first circuit layer with bumps on a substrate, punching an aluminum plate to form recesses corresponding to the bumps, forming openings in a plastic film including a glass fiber layer corresponding to the bumps, pressing the aluminum plate, the plastic film and the substrate, removing the aluminum plate, polishing to level the resulting surface, forming a second circuit layer connected to the first circuit layer, and finally removing the substrate to form the stacked multilayer structure. Because the glass fiber layer in the plastic film is not exposed after polishing, the thickness of the dielectric layer is uniform and the reliability of the circuit layer is improved so as to increase the yield.

Abstract: Disclosed is a method of packaging a chip and a substrate, including the steps of forming a substrate with a thickness ranging from 70 to 150 ?m, which comprises a dielectric layer, a circuit metal layer stacked on the dielectric layer and bonding pads higher than the dielectric layer by 10 to 15 ?m; forming a stabilizing structure around the substrate to provide a receiving space; disposing the chip on the receiving space and bonding the pins of the chip with the bonding pads; and filling up the receiving space under the chip with a filling material to a total thickness ranging from 300 to 850 ?m. Without the plastic molding process, the present invention reduces the cost and the total thickness, and further prevents the substrate from warping by use of the stabilizing fixing structure.

Abstract: Disclosed is a stacked multilayer structure, including a first circuit layer having bumps, a plastic film stacked on the first circuit layer to fill up the space among the bumps so as to form a co-plane, and a second circuit layer formed on the co-plane and connected to the first circuit layer. The plastic film includes a glass fiber layer which is embedded and not exposed. The adhesion between plastic film and the second circuit layer is greatly improved because the glass fiber layer of the plastic film filling up the space among the bumps is not deformed and exposed outwards. Therefore, the yield and reliability of the stacked multilayer structure is increased.

Abstract: A chip support board structure which includes at least a metal substrate, a block layer, a paddle, an insulation layer, a circuit layer and a solder resist is disclosed. The circuit layer connects with the paddle. The material of the block layer is different from that of the metal substrate and the block layer is provided between the metal substrate and the paddle such that the shape and the depth of the paddle is maintained constant and the problem of different depth and easily peeling off is avoided, thereby improving the yield rate of the chip support board.

Abstract: A chip support board structure which includes at least a metal substrate, a block layer, a paddle, an insulation layer, a circuit layer and a solder resist is disclosed. The circuit layer connects with the paddle. The material of the block layer is different from that of the metal substrate and the block layer is provided between the metal substrate and the paddle such that the shape and the depth of the paddle is maintained constant and the problem of different depth and easily peeling off is avoided, thereby improving the yield rate of the chip support board.

Abstract: A method of manufacturing a chip support board structure which includes the steps of forming a metal substrate structure, forming a photo resist pattern, etching the metal substrate structure to form a paddle, removing the photo resist pattern, pressing an insulation layer against the paddle, polishing the insulation layer, forming a circuit layer and forming a solder resist is disclosed. The metal substrate structure is formed by sandwiching a block layer with two metal substrate layers, multilayer. The metal substrate structure is etched under control to an effective depth such that each paddle thus formed has the same shape and depth. Therefore, the method of the present invention can be widely applied to the general mass production processes to effectively solve the problems in the prior arts due to depth differences, such offset, position mismatch and peeling off in the chip support board.

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 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: 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 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 component-embedded printed circuit board includes: a carrier plate having a metalized layer disposed thereon, an electronic component disposed on the metalized layer of the carrier plate, and a metal layer laminated onto the metalized layer having the electronic component disposed thereon by a dielectric film. The carrier plate is then removed to expose the metalized layer. At least one of the metal layer and the metalized layer is patterned to be a circuit layer.

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.