Abstract: A semiconductor package assembly is disclosed having a semiconductor die receiving member configured to accept a semiconductor die in either the flip-chip or the wirebond orientations. First contact sites on a die receiving surface provide electrical connection with a flip-chip component. Second contact sites provide electrical connection with a wirebond component. Electrically conductive traces connect the first and second contact sites with terminal contact sites. The semiconductor package assembly may further include the flip-chip or wirebond component mounted over the die receiving surface. Further, the assembly may also include a mounting substrate in electrical connection with the terminal contact sites.

Abstract: A technique for packaging multiple devices to form a multi-chip module. Specifically, a multi-chip package is coupled to an interposer to form the multi-chip module. The multi-chip package includes a plurality of integrated circuit chips coupled to a carrier. The chips are encapsulated such that conductive elements are exposed through the encapsulant. The conductive elements are electrically coupled to the chips. The interposer is configured such that vias are aligned with the conductive elements. Conductive material may be disposed into the vias to provide signal paths from the integrated circuit chips to conductive balls disposed on the backside of the interposer.

Abstract: Flip-chip semiconductor assemblies, each including integrated circuit (IC) dice and an associated substrate, are electrically tested before encapsulation using an in-line or in-situ test socket or probes at a die-attach station. Those assemblies using “wet” quick-cure epoxies for die attachment may be tested prior to the epoxy being cured by pressing the integrated circuit (IC) dice against interconnection points on the substrate for electrical connection, while those assemblies using “dry” epoxies may be cured prior to testing. In either case, any failures in the dice or in the interconnections between the dice and the substrates can be easily fixed, and the need for the use of known-good-die (KGD) rework procedures during repair is eliminated.

Abstract: A method of manufacturing a stackable package to create a 3-dimensional memory array using ball grid array technology. Specifically, memory chips are coupled to a preformed packages which have alignment features to allow for the stacking of the ball grid arrays. The alignment features are used to align and orient each package with respect to an adjacent package, substrate or printed circuit board. The alignment features also support the weight of the adjacent package during solder ball reflow to maintain stack height and parallelism between packages. Each memory device is serially connected to the adjacent memory device through the vias and solder balls on each package.

Abstract: A method of attaching solder balls to a BGA package using a ball pickup tool. An array of solder balls is formed on a first substrate for interconnecting with conductive sites on another substrate. The ball pickup tool picks up balls with a vacuum suction from a fluidized ball reservoir and utilizes a puff of gas to release the solder ball(s) carried thereon to conductive sites of a substrate for bonding thereto. In another embodiment, the bond pads of a substrate are coated with a flux or adhesive and lowered into a fluidized ball reservoir for direct attachment of solder balls.

Abstract: Flip-chip semiconductor assemblies, each including integrated circuit (IC) dice and an associated substrate, are electrically tested before encapsulation using an in-line or in-situ test socket or probes at a die-attach station. Those assemblies using “wet” quick-cure epoxies for die attachment may be tested prior to the epoxy being cured by pressing the integrated circuit (IC) dice against interconnection points on the substrate for electrical connection, while those assemblies using “dry” epoxies may be cured prior to testing. In either case, any failures in the dice or in the interconnections between the dice and the substrates can be easily fixed, and the need for the use of known-good-die (KGD) rework procedures during repair is eliminated.

Abstract: Flip-chip semiconductor assemblies, each including integrated circuit (IC) dice and an associated substrate, are electrically tested before encapsulation using an in-line or in-situ test socket or probes at a die-attach station. Those assemblies using “wet” quick-cure epoxies for die attachment may be tested prior to the epoxy being cured by pressing the integrated circuit (IC) dice against interconnection points on the substrate for electrical connection, while those assemblies using “dry” epoxies may be cured prior to testing. In either case, any failures in the dice or in the interconnections between the dice and the substrates can be easily fixed, and the need for the use of known-good-die (KGD) rework procedures during repair is eliminated.

Abstract: Methods and apparatuses for encapsulating a microelectronic die or other components in the fabrication of packaged microelectronic devices. In one aspect of the invention, a packaged microelectronic device assembly includes a microelectronic die, a substrate attached to the die, a protective casing covering a portion of the substrate, and a barrier projecting away from the surface of the substrate. The microelectronic die can have an integrated circuit and a plurality of bond-pads operatively coupled to the integrated circuit. The substrate can have a cap-zone defined by an area that is to be covered by the protective casing, a plurality of contact elements arranged in the cap-zone, a plurality of ball-pads arranged in a ball-pad array outside of the cap-zone, and a plurality of conductive lines coupling the contact elements to the ball-pads. The contact elements are electrically coupled to corresponding bond-pads on the microelectronic die, and the protective casing covers the cap-zone.

Abstract: Flip-chip semiconductor assemblies, each including integrated circuit (IC) dice and an associated substrate, are electrically tested before encapsulation using an in-line or in-situ test socket or probes at a die-attach station. Those assemblies using “wet” quick-cure epoxies for die attachment may be tested prior to the epoxy being cured by pressing the integrated circuit (IC) dice against interconnection points on the substrate for electrical connection, while those assemblies using “dry” epoxies may be cured prior to testing. In either case, any failures in the dice or in the interconnections between the dice and the substrates can be easily fixed, and the need for the use of known-good-die (KGD) rework procedures during repair is eliminated.

Abstract: Flip-chip semiconductor assemblies, each including integrated circuit (IC) dice and an associated substrate, are electrically tested before encapsulation using an in-line or in-situ test socket or probes at a die-attach station. Those assemblies using “wet” quick-cure epoxies for die attachment may be tested prior to the epoxy being cured by pressing the integrated circuit (IC) dice against interconnection points on the substrate for electrical connection, while those assemblies using “dry” epoxies may be cured prior to testing. In either case, any failures in the dice or in the interconnections between the dice and the substrates can be easily fixed, and the need for the use of known-good-die (KGD) rework procedures during repair is eliminated.

Abstract: Flip-chip semiconductor assemblies, each including integrated circuit (IC) dice and an associated substrate, are electrically tested before encapsulation using an in-line or in-situ test socket or probes at a die-attach station. Those assemblies using “wet” quick-cure epoxies for die attachment may be tested prior to the epoxy being cured by pressing the integrated circuit (IC) dice against interconnection points on the substrate for electrical connection, while those assemblies using “dry” epoxies may be cured prior to testing. In either case, any failures in the dice or in the interconnections between the dice and the substrates can be easily fixed, and the need for the use of known-good-die (KGD) rework procedures during repair is eliminated.

Abstract: An anisotropic electrically conducting interconnect is disclosed in which an adhesive comprising particles having a breakable coating of at least one electrically nonconductive material is compressed between a first contact and a second contact. Compression to two contacts breaks the breakable coating exposing an electrically conducting material which makes contact with the first and second contacts. The electrically conducting material may be a metal conductor or a two-part reactive conductive resin/catalyst system. Also disclosed are processes for making such electrical interconnects and adhesives for use in making electrical interconnect.

Abstract: A semiconductor component includes a substrate and multiple stacked, encapsulated semiconductor dice on the substrate. A first die is back bonded to the substrate and encapsulated in a first encapsulant, and a second die is back bonded to the first encapsulant. The first encapsulant has a planar surface for attaching the second die, and can also include locking features for the second die. The component also includes a second encapsulant encapsulating the second die and forming a protective body for the component. A method for fabricating the component includes the steps of attaching the first die to the substrate, forming the first encapsulant on the first die, attaching the second die to the first encapsulant, and forming the second encapsulant on the second die.

Abstract: A semiconductor component includes a substrate and multiple stacked, encapsulated semiconductor dice on the substrate. A first die is back bonded to the substrate and encapsulated in a first encapsulant, and a second die is back bonded to the first encapsulant. The first encapsulant has a planar surface for attaching the second die, and can also include locking features for the second die. The component also includes a second encapsulant encapsulating the second die and forming a protective body for the component. A method for fabricating the component includes the steps of attaching the first die to the substrate, forming the first encapsulant on the first die, attaching the second die to the first encapsulant, and forming the second encapsulant on the second die.

Abstract: A semiconductor component includes a substrate and multiple stacked, encapsulated semiconductor dice on the substrate. A first die is back bonded to the substrate and encapsulated in a first encapsulant, and a second die is back bonded to the first encapsulant. The first encapsulant has a planar surface for attaching the second die, and can also include locking features for the second die. The component also includes a second encapsulant encapsulating the second die and forming a protective body for the component. A method for fabricating the component includes the steps of attaching the first die to the substrate, forming the first encapsulant on the first die, attaching the second die to the first encapsulant, and forming the second encapsulant on the second die.

Abstract: An anisotropic electrically conducting interconnect is disclosed in which an adhesive comprising particles having a breakable coating of at feast one electrically nonconductive material is compressed between a first contact and a second contact. Compression to two contacts breaks the breakable coating exposing an electrically conducting material which makes contact with the first and second contacts. The electrically conducting material may be a metal conductor or a two-part reactive conductive resin/catalyst system. Also disclosed are processes for making such electrical interconnects and adhesives for use in making electrical interconnect.

Abstract: An anisotropic electrically conducting interconnect is disclosed in which an adhesive comprising particles having a breakable coating of at least one electrically nonconductive material is compressed between a first contact and a second contact. Compression to two contacts breaks the breakable coating exposing an electrically conducting material which makes contact with the first and second contacts. The electrically conducting material may be a metal conductor or a two-part reactive conductive resin/catalyst system. Also disclosed are processes for making such electrical interconnects and adhesives for use in making electrical interconnect.

Abstract: A thin-stacked ball grid array (BGA) package is created by coupling a semi-conducting die to each of the opposing faces of an interposer having bond pads and circuitry on both faces. Solder balls on either side of each die and/or the interposer provide interconnects for stacking packages and also provide interconnects for module mounting. Each die may be electrically coupled to the interposer using wire bonds, “flip-chip” techniques, or other techniques as appropriate. A redistribution layer may also be formed on the outer surface of a bumped die to create connections between the die circuitry, ball pads and/or wire bonding pads. Because the two die are coupled to each other on opposite faces of the interposer, each package is extremely space-efficient. Individual packages may be stacked together prior to encapsulation or molding to further improve the stability and manufacturability of the stacked package.

Abstract: Apparatus and method for attaching, assembling, and/or mounting a substrate to any semiconductor device or a flip-chip type semiconductor device.

Abstract: A technique for packaging multiple devices to form a multi-chip module. Specifically, a multi-chip package is coupled to an interposer to form the multi-chip module. The multi-chip package includes a plurality of integrated circuit chips coupled to a carrier. The chips are encapsulated such that conductive elements are exposed through the encapsulant. The conductive elements are electrically coupled to the chips. The interposer is configured such that vias are aligned with the conductive elements. Conductive material may be disposed into the vias to provide signal paths from the integrated circuit chips to conductive balls disposed on the backside of the interposer.