Abstract: There is provided a method of fabricating a package substrate. The method may include forming an isolation trench in a conductive layer, and forming a first dielectric layer on the conductive layer to provide an isolation wall portion filling the isolation trench. The method may include recessing the conductive layer to form circuit patterns in circuit trenches defined and separated by the isolation wall portion. The method may include forming a second dielectric layer covering the circuit patterns, and patterning the first and second dielectric layers to expose portions of the circuit patterns. The exposed portions of the circuit patterns may act as connectors.

Abstract: A semiconductor package may include a semiconductor device mounted on a package substrate, a conductive roof located over the semiconductor device, a plurality of conductive walls disposed on the package substrate and arrayed in a closed loop line surrounding the semiconductor device. Conductive pillars may be disposed in regions between the conductive walls on the package substrate and bonded to the conductive roof. The semiconductor package may include a first dielectric layer filling a space between the package substrate and the conductive roof.

Abstract: There is provided a method of fabricating a package substrate. The method may include forming an isolation trench in a conductive layer, and forming a first dielectric layer on the conductive layer to provide an isolation wall portion filling the isolation trench. The method may include recessing the conductive layer to form circuit patterns in circuit trenches defined and separated by the isolation wall portion. The method may include forming a second dielectric layer covering the circuit patterns, and patterning the first and second dielectric layers to expose portions of the circuit patterns. The exposed portions of the circuit patterns may act as connectors.

Abstract: A semiconductor package may include a semiconductor device mounted on a package substrate, a conductive roof located over the semiconductor device, a plurality of conductive walls disposed on the package substrate and arrayed in a closed loop line surrounding the semiconductor device. Conductive pillars may be disposed in regions between the conductive walls on the package substrate and bonded to the conductive roof. The semiconductor package may include a first dielectric layer filling a space between the package substrate and the conductive roof.

Abstract: Disclosed herein are semiconductor packages. A semiconductor package may include a substrate configured to include a first face and a second face opposite the first face and to have a recess formed in the first face. The semiconductor package may include a first semiconductor chip disposed on the bottom of the recess. The semiconductor package may include a second semiconductor chip disposed on the second face of the substrate. The semiconductor package may include a third semiconductor chip disposed over the first face of the substrate and the first semiconductor chip. The semiconductor package may include a fourth semiconductor chip disposed over the third semiconductor chip.

Abstract: Disclosed herein are semiconductor packages. A semiconductor package may include a substrate configured to include a first face and a second face opposite the first face and to have a recess formed in the first face. The semiconductor package may include a first semiconductor chip disposed on the bottom of the recess. The semiconductor package may include a second semiconductor chip disposed on the second face of the substrate. The semiconductor package may include a third semiconductor chip disposed over the first face of the substrate and the first semiconductor chip. The semiconductor package may include a fourth semiconductor chip disposed over the third semiconductor chip.

Abstract: Disclosed is a ball grid array package with stacked center pad chips, which realizes a BGA package with stacked chips using center pad type semiconductor chips, and a method for manufacturing the same. The semiconductor chips are glued on each of upper and lower circuit boards, which have active surfaces facing each other; the chip pads are connected to each of the upper and lower circuit boards with gold wires; the upper and lower circuit boards are joined together with bumps interposed between them for electrical connection; the upper circuit board is included in a package mold; and the opposite ends of the lower circuit board are exposed to the lower portion of the package mold. The lower circuit board can be made of flexible insulation film. The exposed opposite ends of the lower circuit board can have solder balls formed thereon. Also, the opposite ends of the lower circuit board may be joined to a printed circuit board. Solder balls may be formed on the lower surface of the printed circuit board.

Abstract: Disclosed is a ball grid array package with stacked center pad chips, which realizes a BGA package with stacked chips using center pad type semiconductor chips, and a method for manufacturing the same. The semiconductor chips are glued on each of upper and lower circuit boards, which have active surfaces facing each other; the chip pads are connected to each of the upper and lower circuit boards with gold wires; the upper and lower circuit boards are joined together with bumps interposed between them for electrical connection; the upper circuit board is included in a package mold; and the opposite ends of the lower circuit board are exposed to the lower portion of the package mold. The lower circuit board can be made of flexible insulation film. The exposed opposite ends of the lower circuit board can have solder balls formed thereon. Also, the opposite ends of the lower circuit board may be joined to a printed circuit board. Solder balls may be formed on the lower surface of the printed circuit board.

Abstract: Disclosed is a ball grid array package with stacked center pad chips, which realizes a BGA package with stacked chips using center pad type semiconductor chips, and a method for manufacturing the same. The semiconductor chips are glued on each of upper and lower circuit boards, which have active surfaces facing each other; the chip pads are connected to each of the upper and lower circuit boards with gold wires; the upper and lower circuit boards are joined together with bumps interposed between them for electrical connection; the upper circuit board is included in a package mold; and the opposite ends of the lower circuit board are exposed to the lower portion of the package mold. The lower circuit board can be made of flexible insulation film. The exposed opposite ends of the lower circuit board can have solder balls formed thereon. Also, the opposite ends of the lower circuit board may be joined to a printed circuit board. Solder balls may be formed on the lower surface of the printed circuit board.

Abstract: The present invention relates to manufacture of a stacked chip package. A first substrate including a first center window is attached to a first semiconductor chip having a plurality of bonding pads arranged on the center part. A first bonding wire is formed to connect the first semiconductor chip and the first substrate. A second substrate including a second center window is attached to a second semiconductor chip having a plurality of bonding pads arranged on the center part. A second bonding wire is formed to connect the second semiconductor chip end the second substrate. The backsides of the resulting first and the second semiconductor chips are attached. A third bonding wire is formed to connect the first and the second substrates. A molding body is formed to overlay the first, the second and the third bonding wires. A conductive ball is adhered to the first substrate.

Abstract: Disclosed is a ball grid array package with stacked center pad chips, which realizes a BGA package with stacked chips using center pad type semiconductor chips, and a method for manufacturing the same. The semiconductor chips are glued on each of upper and lower circuit boards, which have active surfaces facing each other; the chip pads are connected to each of the upper and lower circuit boards with gold wires; the upper and lower circuit boards are joined together with bumps interposed between them for electrical connection; the upper circuit board is included in a package mold; and the opposite ends of the lower circuit board are exposed to the lower portion of the package mold. The lower circuit board can be made of flexible insulation film. The exposed opposite ends of the lower circuit board can have solder balls formed thereon. Also, the opposite ends of the lower circuit board may be joined to a printed circuit board. Solder balls may be formed on the lower surface of the printed circuit board.

Abstract: The present invention provides a method for manufacturing a stacked chip package comprising the steps of attaching a first substrate including a first center window on a first semiconductor chip having a plurality of bonding pads arranged on the center part; forming a first bonding wire connecting the first semiconductor chip and the first substrate; attaching a second substrate including a second center window on a second semiconductor chip having a plurality of bonding pads arranged on the center part; forming a second bonding wire connecting the second semiconductor chip and the second substrate; attaching the backsides of the resulting first and the second semiconductor chips; forming a third bonding wire connecting the first and the second substrates; forming a molding body overlaying the first, the second and the third bonding wires; and adhering a conductive ball to the first substrate.