Abstract: A package-on-package semiconductor assembly is characterized by a semiconductor device positioned in a dielectric recess of a core base and surrounded by an array of metal posts. The recess in the core provides lateral displacement control between the device and the metal posts, and the minimal height of the metal posts needed for the vertical connection between two both opposite sides of the core base can be reduced by the amount equal to the depth of the recess. Further, another semiconductor device is disposed over a top surface of the core base and is electrically coupled to the semiconductor device in the dielectric recess through a buildup circuitry under a bottom surface of the core base.

Abstract: A face-to-face semiconductor assembly is characterized by a semiconductor device positioned in a dielectric recess of a core base and surrounded by an array of metal posts. The recess in the core provides lateral displacement control between the device and the metal posts, and the minimal height of the metal posts needed for the vertical connection between both opposite sides of the core base can be reduced by the amount equal to the depth of the recess. Further, the semiconductor device is face-to-face electrically coupled to another semiconductor device through a buildup circuitry therebetween.

Abstract: A method of making a stackable wiring board is characterized by positioning an electronic component in a dielectric recess to realize the thickness reduction of the wiring board and sidewalls of the recess can confine the dislocation of the electronic component to avoid misalignment between buildup circuitry and the electronic component. An array of metal posts that provide vertical electrical connections are formed by using the same metal carrier that forms the recess, so that the predetermined distance and relative location between metal posts and pads/bumps of the electronic component can be maintained.

Abstract: A face-to-face semiconductor assembly is characterized in that an encapsulated device having a first semiconductor chip surrounded by an array of vertical connecting elements in an encapsulant is stacked on and electrically coupled to a thermally enhanced device having a second semiconductor chip accommodated in a cavity of a thermal board. The first and second semiconductor chips are face-to-face mounted on two opposite sides of a first routing circuitry and is further electrically connected to the vertical connecting elements through the first routing circuitry. The thermal board has a heat spreader to provide thermal dissipation for the second semiconductor chip. The first routing circuitry provides primary fan-out routing for the first and second semiconductor chips, whereas the vertical connecting elements provide electrical contacts for next-level connection.

Abstract: A wiring board with embedded component and integrated stiffener is characterized in that an embedded semiconductor device, a first routing circuitry, an encapsulant and an array of vertical connecting elements are integrated as an electronic component disposed within a through opening of a stiffener, and a second routing circuitry is disposed beyond the through opening of the stiffener and extends over the stiffener. The mechanical robustness of the stiffener can prevent the wiring board from warping. The embedded semiconductor device is electrically coupled to the first routing circuitry and surrounded by the vertical connecting elements in electrical connection with the first and second routing circuitries. The first routing circuitry provides primary fan-out routing for another semiconductor device to be assembled on the wiring board, whereas the second routing circuitry not only provides further fan-out wiring structure, but also mechanically binds the electronic component with the stiffener.

Abstract: A wiring board with dual stiffeners and integrated dual routing circuitries is characterized in that first and second routing circuitries are positioned within and beyond a through opening of a first stiffener, respectively, and an array of vertical connecting channels are disposed on the second routing circuitry and laterally surrounded by a second stiffener. The mechanical robustness of the first and second stiffeners can prevent the wiring board from warping. The vertical connecting channels can offer electrical contacts for next-level connection. The first routing circuitry, positioned within the through opening of the first stiffener, can provide primary fan-out routing, whereas the second routing circuitry not only provides further fan-out wiring structure for the first routing circuitry, but also mechanically binds the first routing circuitry with the first stiffener.

Abstract: A face-to-face semiconductor assembly is characterized in that first and second semiconductor devices are face-to-face mounted on two opposite sides of a first routing circuitry and is further electrically connected to an interconnect board through the first routing circuitry. The interconnect board has a heat spreader to provide thermal dissipation for the second semiconductor device, and a second routing circuitry formed on the heat spreader and electrically coupled to the first routing circuitry. The first routing circuitry provides primary fan-out routing for the first and second semiconductor devices, whereas the second routing circuitry provides further fan-out wiring structure for the first routing circuitry.

Abstract: A semiconductor assembly with built-in stiffener and integrated dual routing circuitries is characterized in that a semiconductor device and a first routing circuitry are positioned within a through opening of a stiffener whereas a second routing circuitry extends to an area outside of the through opening of the stiffener. The mechanical robustness of the stiffener can prevent the assembly from warping. The first routing circuitry can enlarge the pad size and pitch of the semiconductor device, whereas the second routing circuitry not only provides further fan-out wiring structure, but also mechanically binds the first routing circuitry with the stiffener.

Abstract: A coreless substrate includes a build-up circuitry, a warping controller and an optional stiffener. The warping controller is adhered to the solder ball attachment side of the build-up circuitry and provides mechanical support for the coreless substrate, whereas the optional stiffener is positioned around peripheral edges of the coreless substrate at the chip attachment side of the build-up circuitry and provides mechanical support for the peripheral area of the coreless substrate.

Abstract: A method of making a wiring board is characterized by the provision of moisture inhibiting caps covering interfaces between an electrical isolator/optional metal posts and a surrounding plastic material. In a preferred embodiment, the electrical isolator and metal posts are bonded to the resin core by an adhesive substantially coplanar with the metal layers on two opposite sides of the resin core, the metal posts and a thermally conductive slug that includes the electrical isolator at smoothed lapped top and bottom surfaces, so that a metal bridge can be deposited on the adhesive at the smoothed lapped bottom surface to completely cover interfaces between the electrical isolator/metal posts and the surrounding plastic material. Conductive traces are also deposited on the smoothed lapped top surface to provide electrical contacts for chip connection and electrically coupled to the metal posts.

Abstract: A wiring board with embedded interposer is characterized in that the embedded interposer is integrated with a stiffener and a build-up circuitry is deposited on the stiffener, so that the mechanical robustness of the stiffener can prevent the entire wiring board from warping. The interposer provides primary fan-out routing whereas the build-up circuitry provides further fan-out routing and can further enlarge the pad size and pitch of the interposer.

Abstract: A wiring board with integrated interposer and dual wiring structures is characterized in that an interposer and a first wiring structure are positioned within a through opening of a stiffener whereas a second wiring structure is disposed beyond the through opening of the stiffener. The mechanical robustness of the stiffener can prevent the wiring board from warping. The interposer provides primary fan-out routing for a semiconductor device to be assembled thereon. The first wiring structure can further enlarge the pad size and pitch of the interposer, whereas the second wiring structure not only provides further fan-out wiring structure, but also mechanically binds the first wiring structure with the stiffener.

Abstract: The present invention relates to a method of making a semiconductor package with package-on-package stacking capability. In accordance with a preferred embodiment, the method is characterized by the step of attaching a chip-on-interposer subassembly on a metallic carrier with the chip inserted into a cavity of the metallic carrier, and the step of selectively removing portions of the metallic carrier to define a heat spreader for the chip. The heat spreader can provide thermal dissipation, electromagnetic shielding and moisture barrier, whereas the interposer provides a CTE-matched interface and fan-out routing for the chip.

Abstract: A wiring board with integrated dual wiring structures is characterized in that first and second wiring structures are positioned within and beyond a through opening of a stiffener, respectively. The mechanical robustness of the stiffener can prevent the wiring board from warping. The first wiring structure, positioned within the through opening of the stiffener, can provide primary fan-out routing, whereas the second wiring structure not only provides further fan-out wiring structure for the first wiring structure, but also mechanically binds the first wiring structure with the stiffener.

Abstract: A method of making a semiconductor device with face-to-face chips on interposer includes the step of attaching a chip-on-interposer subassembly on a heat spreader with the chip inserted into a cavity of the heat spreader so that the heat spreader provides mechanical support for the interposer. The heat spreader also provides thermal dissipation, electromagnetic shielding and moisture barrier for the enclosed chip. In the method, a second chip is also electrically coupled to a second surface of the interposer and an optional second heat spreader is attached to the second chip.

Abstract: The present invention relates to a method of making a semiconductor package with package-on-package stacking capability. In accordance with a preferred embodiment, the method is characterized by the step of attaching a chip-on-interposer subassembly on a metallic carrier with the chip inserted into a cavity of the metallic carrier, and the step of selectively removing portions of the metallic carrier to define a heat spreader for the chip. The heat spreader can provide thermal dissipation, electromagnetic shielding and moisture barrier, whereas the interposer provides a CTE-matched interface and fan-out routing for the chip.

Abstract: A method of making a semiconductor assembly is characterized by the step of attaching a chip-on-interposer subassembly on a base carrier with the chip inserted into a through opening of the base carrier and the interposer laterally extending beyond the through opening. The base carrier provides a platform for the chip-on-interposer subassembly attachment, whereas the interposer provides primary fan-out routing for the chip. In the method, a buildup circuitry is electrically coupled to the interposer and an optional cover sheet or additional buildup circuitry can be provided on the chip.

Abstract: A method of making a semiconductor device with face-to-face chips on interposer includes the step of attaching a chip-on-interposer subassembly on a heat spreader with the chip inserted into a cavity of the heat spreader so that the heat spreader provides mechanical support for the interposer. The heat spreader also provides thermal dissipation, electromagnetic shielding and moisture barrier for the enclosed chip. In the method, a second chip is also electrically coupled to a second surface of the interposer and an optional second heat spreader is attached to the second chip.

Abstract: A method of making a semiconductor device is characterized by the step of attaching a chip-on-interposer subassembly to a heat spreader with the chip inserted into a cavity of the heat spreader and the interposer laterally extending beyond the cavity. The interposer backside process is executed after the chip-on-interposer attachment and encapsulation to form the finished interposer. The heat spreader provides thermal dissipation, and the finished interposer provides primary fan-out routing for the chip. In the method, a buildup circuitry is electrically coupled to the interposer to provide further fan-out routing.

Abstract: A method of making a wiring board having a metal slug incorporated in a resin core is characterized by the provision of a moisture inhibiting cap covering interfaces between metal and plastic. In a preferred embodiment, the metal slug is bonded to the resin core by an adhesive substantially coplanar with the metal slug and the metal layers on two opposite sides of the resin core at smoothed lapped top and bottom surfaces so that a metal bridge can be deposited on the adhesive at the smoothed lapped bottom surface to completely cover interfaces between the metal slug and the surrounding plastic material. In the method, conductive traces are also deposited on the resin core at the smoothed lapped top surface so as to provide electrical contacts for chip connection.