Abstract: The wiring substrate includes a cavity and a plurality of metal leads disposed around the cavity. The metal leads are bonded with a resin compound and provide horizontal and vertical routing for a semiconductor device to be disposed in the cavity. The resin compound fills in spaces between the metal leads and surrounds the cavity and provides a dielectric platform for a re-distribution layer or a build-up circuitry optionally deposited thereon.

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. A plurality of plated through holes are formed to provide vertical electrical connections between dual buildup circuitries, thereby providing the wiring board with stacking capability.

Abstract: The leadframe substrate includes a routing circuitry disposed on a compound layer and electrically connects an electronic component encapsulated in the compound layer to metal leads. The compound layer fills in spaces between the metal leads and provides a dielectric platform for the routing circuitry deposited thereon. The routing circuitry laterally extends on the compound layer and is electrically coupled to the electronic component and the metal leads.

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 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: An interconnect substrate includes vertical connection channels around a cavity. The vertical connection channels are made of a combination of metal posts and metallized vias. The cavity includes a recess in a core layer and an aperture in a stiffener. The metal posts, disposed over the top surface of the core layer, are sealed in the stiffener and are electrically connected to a buildup circuitry adjacent to the bottom surface of the core layer. The minimal height of the metal posts needed for the vertical connection can be reduced by the amount equal to the depth of the recess. The buildup circuitry is electrically connected to the metal posts through the metallized vias.

Abstract: A method of making an interconnect substrate includes steps of: providing a base and a plurality of posts projecting from the base, providing a dielectric compound on the base, forming a top routing circuitry on the dielectric compound and electrically coupled to the posts; and selectively removing portions of the base to form a plurality of terminals. The terminals are below the posts and extend laterally from the posts to provide electrical contacts underneath the dielectric compound. The dielectric compound covers sidewalls of the posts and provides a dielectric platform for the top routing circuitry deposited thereon. The top routing circuitry laterally extends on the dielectric compound and is electrically connected to the terminals by the posts.

Abstract: An interconnect substrate having vertical connection channels around a cavity is characterized in that contact pads are exposed from the cavity and the vertical connection channels are made of a combination of metal posts and metallized vias. The cavity includes a recess in a core layer and an aperture in a stiffener. The metal posts, disposed over the top surface of the core layer, are sealed in the stiffener and are electrically connected to a buildup circuitry adjacent to the bottom surface of the core layer. The minimal height of the metal posts needed for the vertical connection can be reduced by the amount equal to the depth of the recess. The buildup circuitry is electrically connected to the metal posts through the metallized vias and provides the contact pads exposed from the cavity for device connection.

Abstract: The leadframe substrate includes an isolator incorporated with metal leads by a compound layer. The metal leads are disposed about sidewalls of the isolator and provide horizontal and vertical routing for a semiconductor device to be assembled on the isolator. The compound layer covers the sidewalls of the isolator and fills in spaces between the metal leads, and provides robust mechanical bonds between the metal leads and the isolator.

Abstract: A wiring board includes an electrical isolator laterally surrounded by a base board and a molding compound. The electrical isolator is inserted into a through opening of the base board and has a thickness greater than that of the base board. The molding compound covers the top side of the base board and sidewalls of the electrical isolator, and provides a reliable interface for deposition of a routing circuitry thereon. The base board can serve as an alignment guide for isolator placement or/and provide another routing to enhance electrical routing flexibility for the wiring board.

Abstract: A thermally enhanced semiconductor assembly with three dimensional integration includes a semiconductor chip electrically coupled to a wiring board by bonding wires. A heat spreader that provides an enhanced thermal characteristic for the semiconductor chip is disposed in a through opening of a wiring structure. Another wiring structure disposed on the heat spreader not only provides mechanical support, but also allows heat spreading and electrical grounding for the heat spreader by metallized vias. The bonding wires provide electrical connections between the semiconductor chip and the wiring board for interconnecting the semiconductor chip to terminal pads provided in the wiring board.

Abstract: A thermally enhanced semiconductor assembly with three dimensional integration includes a stacked semiconductor sub-assembly electrically coupled to a wiring board by bonding wires. A heat spreader that provides an enhanced thermal characteristic for the stacked semiconductor sub-assembly is disposed in a through opening of a wiring structure. Another wiring structure disposed on the heat spreader not only provides mechanical support, but also allows heat spreading and electrical grounding for the heat spreader by metallized vias. The bonding wires provide electrical connections between the sub-assembly and the wiring board for interconnecting devices assembled in the sub-assembly to terminal pads provided in the wiring board.

Abstract: A thermally enhanced semiconductor assembly with three dimensional integration includes a first component and a second component face-to-face mounted together. A heat spreader that provides an enhanced thermal characteristic for the semiconductor assembly is disposed in a through opening of a routing circuitry. Another routing circuitry disposed on the heat spreader not only provides mechanical support, but also allows heat spreading and electrical grounding for the heat spreader by metallized vias.

Abstract: A semiconductor assembly includes an anti-warping controller, a semiconductor device, a balance layer and a first routing circuitry positioned within a through opening of a stiffener and a second routing circuitry positioned outside of the through opening of the stiffener and electrically connected to the first routing circuitry and a vertical connecting element of the stiffener. The mechanical robustness of the stiffener and the anti-warping controller can prevent the assembly from warping, whereas the vertical connecting element of the stiffener provides electrical connection between two opposite sides of the stiffener. 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 semiconductor assembly includes a face-to-face semiconductor sub-assembly electrically coupled to a circuit board by bonding wires. The face-to-face semiconductor sub-assembly includes top and bottom devices assembled on opposite sides of a routing circuitry, and is disposed in a through opening of the circuit board. The bonding wires provide electrical connections between the routing circuitry and the circuit board to interconnect the devices face-to-face assembled in the sub-assembly with the circuit board for next-level connection from two opposite sides of the circuit board.

Abstract: A semiconductor assembly with three dimensional integration includes a face-to-face semiconductor sub-assembly electrically coupled to a heat spreader by bonding wires. The face-to-face semiconductor sub-assembly includes top and bottom devices assembled on opposite sides of a first routing circuitry, and the heat spreader includes a metal plate and a second routing circuitry on the metal plate.

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 forming through openings that extend through a metallic carrier between first and second surfaces of the metallic carrier, attaching a chip-on-interposer subassembly on the metallic carrier using an adhesive, with the chip inserted into a cavity of the metallic carrier, and with the chip-on-interposer subassembly attached to the metallic carrier, forming first and second buildup circuitry on a first surface of the interposer and the second surface of the metallic carrier, respectively, and subsequently forming plated through holes that extend into the through openings to provide electrical and thermal connections between the first and second buildup circuitry. The method and resulting device advantageously provides vertical signal routing and stacking capability for a semiconductor package.

Abstract: A wiring board includes a low CTE (coefficient of thermal expansion) and high thermal conductivity isolator incorporated in a resin laminate by an adhesive and a bridging element disposed over the isolator and the resin laminate and electrically coupled to a first routing circuitry on the isolator and a second routing circuitry on the resin laminate. The isolator provides CTE-compensated contact interface for a semiconductor chip to be assembled thereon, and also provides primary heat conduction for the chip. The bridging element offers a reliable connecting channel for interconnecting contact pads on the isolator to terminal pads on the resin laminate.

Abstract: An interconnect substrate having vertical connection channels around a cavity is characterized in that contact pads are exposed from the cavity and the vertical connection channels are made of a combination of metal posts and metallized vias. The cavity includes a recess in a core layer and an aperture in a stiffener. The metal posts, disposed over the top surface of the core layer, are sealed in the stiffener and are electrically connected to a buildup circuitry adjacent to the bottom surface of the core layer. The minimal height of the metal posts needed for the vertical connection can be reduced by the amount equal to the depth of the recess. The buildup circuitry is electrically connected to the metal posts through the metallized vias and provides the contact pads exposed from the cavity for device connection.

Abstract: A semiconductor assembly includes an encapsulated device and a thermally enhanced device face-to-face mounted together through first and second routing circuitries and a heat spreader that provides thermal dissipation and electromagnetic shielding. The encapsulated device has a first semiconductor chip sealed in an encapsulant, whereas the thermally enhanced device has a second semiconductor chip thermally conductible to a shielding lid of the heat spreader and laterally surrounded by posts of the heat spreader. The first and second semiconductor chips are mounted on two opposite sides of the first routing circuitry, and the second routing circuitry is disposed on the shielding lid and electrically coupled to the first routing circuitry by bumps. The first and second routing circuitries provide staged fan-out routing for the first and second semiconductor chips.