Abstract: A stackable package to create a 3-dimensional memory array using ball grid array technology. Specifically, memory chips are coupled to a pre-formed 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 stackable package to create a 3-dimensional memory array using ball grid array technology. Specifically, memory chips are coupled to a pre-formed 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 semiconductor card includes a printed circuit substrate upon which is mounted a card circuit including one or more semiconductor components such as dice or packages. External contacts link the card circuit to the circuit of another apparatus by removable insertion therein. The substrate is defined by a peripheral opening in a surrounding frame, which may be part of a multiframe strip. The substrate is connected to the frame by connecting segments. The card includes a first plastic casting molded to the substrate and encapsulating the semiconductor components while leaving a peripheral portion of the substrate uncovered. A second plastic casting is molded to the peripheral portion to abut the first plastic casting and form the card periphery. A method for fabricating the semiconductor card is also included.

Abstract: An encapsulation mold for forming an encapsulation layer over a semiconductor assembly is disclosed. A semiconductor assembly with multiple semiconductor dies secured to a single semiconductor support structure is inserted into an encapsulation mold. The mold contains a first section and a second section, which form a cavity around the assembly. The mold contains an aperture for transferring encapsulating material into the mold cavity. One of the mold sections has a design feature, such as a raised rib or groove interconnecting at approximately the separation or saw-cut regions of the individual dies of the assembly. Encapsulation material is inserted into the mold cavity until the cavity is filled. The mold section design feature shapes the top surface of the encapsulation layer. The mold is removed leaving the exterior surface of the encapsulation layer patterned with the design feature.

Abstract: A ball grid array assembly includes a package cover that encapsulates a die and a portion of a substrate to which the die is attached, including an edge of the substrate. Encapsulation of the substrate edge by the cover reduces penetration of moisture or other contaminants into the substrate. The cover includes a rib that extends to contact a circuit board to which the ball grid array assembly is connected. With such a rib, planarity between the circuit board and the substrate is maintained during soldering.

Abstract: A method and apparatus for applying a protective ring about the perimeter of an exposed die face. Specifically, a semiconductor chip is coupled to the upper surface of a substrate. The edges of the semiconductor chip are protected by a molding compound which is disposed about the perimeter of the chip and on all or a portion of the substrate. The molding system which is used to apply the protective ring comprises three molding plates and does not require a vacuum-based system to hold the package stationary during the encapsulation process. By not applying a molding compound on the top surface of the semiconductor chip, no height is added to the package.

Abstract: An encapsulation method enabling high throughput production of semiconductor die packages. In an exemplary embodiment, a mold is provided with an upper mold platen having a plurality of cavities for encapsulating interconnections on a first side of a multi-chip carrier substrate. The mold further includes a lower mold platen having a cavity for encapsulating substantially the entire second side of the carrier substrate, including a plurality IC chips mounted thereon. Substrate support elements, in the form of standoff pins, are provided for supporting the carrier substrate during the encapsulation process to prevent substrate deflection. The standoff pins may be integral to a mold cavity or may be removable. The standoff pins may further be aligned along lines representing individual device package edges. Cutting along marks left in the encapsulant by the support elements provides individual device packages.

Abstract: An encapsulation mold for forming an encapsulation layer over a semiconductor assembly is disclosed. A semiconductor assembly with multiple semiconductor dies secured to a single semiconductor support structure is inserted into an encapsulation mold. The mold contains a first section and a second section, which form a cavity around the assembly. The mold contains an aperture for transferring encapsulating material into the mold cavity. One of the mold sections has a design feature, such as a raised rib or groove interconnecting at approximately the separation or saw-cut regions of the individual dies of the assembly. Encapsulation material is inserted into the mold cavity until the cavity is filled. The mold section design feature shapes the top surface of the encapsulation layer. The mold is removed leaving the exterior surface of the encapsulation layer patterned with the design feature.

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: A semiconductor card includes a printed circuit substrate upon which is mounted a card circuit including one or more semiconductor components such as dice or packages. External contacts link the card circuit to the circuit of another apparatus by removable insertion therein. The substrate is defined by a peripheral opening in a surrounding frame, which may be part of a multiframe strip. The substrate is connected to the frame by connecting segments. The card includes a first plastic casting molded to the substrate and encapsulating the semiconductor components while leaving a peripheral portion of the substrate uncovered. A second plastic casting is molded to the peripheral portion to abut the first plastic casting and form the card periphery. A method for fabricating the semiconductor card is also included.

Abstract: The present invention is directed toward methods and apparatuses for encapsulating a microelectronic die or another type of microelectronic device. One aspect of the present invention is directed toward packaging a microelectronic die that is attached to either a first surface or a second surface of a substrate. The die can be encapsulated by positioning the die in a cavity of a substrate and sealing the substrate to the substrate. The method can further include injecting an encapsulation compound into the cavity at a first end of the substrate to move along the first surface of the substrate. This portion of the compound defines a first flow of compound along the first surface that moves in a first direction from a first end of the substrate toward a second end of the substrate.

Abstract: The present invention is directed toward methods and apparatuses for encapsulating a microelectronic die or another type of microelectronic device. One aspect of the present invention is directed toward packaging a microelectronic die that is attached to either a first surface or a second surface of a substrate. The die can be encapsulated by positioning the die in a cavity of a substrate and sealing the substrate to the substrate. The method can further include injecting an encapsulation compound into the cavity at a first end of the substrate to move along the first surface of the substrate. This portion of the compound defines a first flow of compound along the first surface that moves in a first direction from a first end of the substrate toward a second end of the substrate.

Abstract: The invention provides methods for packaging for electronic devices that are light or other radiation-sensitive, such as image sensors including CCD or CMOS chips. In one embodiment of the invention, an image sensor package is assembled by surrounding a chip with a barrier of transfer mold compound and covering the chip with a transparent lid. In another embodiment of the invention, the perimeter area of a chip, including interconnections such as wire bonds and bond pads, is encapsulated with a liquid dispensed epoxy, and a transparent lid is attached. In yet another embodiment of the invention, chip encapsulation is accomplished with a unitary shell of entirely transparent material. In yet another embodiment of the invention, a substrate-mounted chip and a transparent lid are loaded into a transfer mold that holds them in optimal alignment. The transfer mold is then filled with molding compound to encapsulate the chip and interconnections, and to retain the transparent lid.

Abstract: The present invention is directed toward methods and apparatuses for encapsulating a microelectronic die or another type of microelectronic device. One aspect of the present invention is directed toward packaging a microelectronic die that is attached to either a first surface or a second surface of a substrate. The die can be encapsulated by positioning the die in a cavity of a substrate and sealing the substrate to the substrate. The method can further include injecting an encapsulation compound into the cavity at a first end of the substrate to move along the first surface of the substrate. This portion of the compound defines a first flow of compound along the first surface that moves in a first direction from a first end of the substrate toward a second end of the substrate.

Abstract: A method for fabricating a semiconductor package is performed using a mold tooling fixture having a mold cavity and a pair of flash control cavities on either side of the mold cavity. The semiconductor package includes a substrate and a semiconductor die attached to the substrate. The substrate includes a pattern of conductors wire bonded to the die, and an array of solder balls bonded to ball bonding pads on the conductors. In addition, the substrate includes a die encapsulant encapsulating the die, and a wire bond encapsulant encapsulating the wire bonds. During molding of the wire bond encapsulant, the flash control cavities collect flash, and provide pressure relief for venting the mold cavity. In addition, the flash control cavities restrict the flash to a selected area of the package substrate, such that the ball bonding pads and solder balls are not contaminated.

Abstract: The invention provides improved packaging for electronic devices that are light or other radiation-sensitive, such as image sensors including CCD or CMOS chips. Methods of assembly are also provided. In one embodiment of the invention, an image sensor package is assembled by surrounding a chip with a barrier of transfer mold compound and covering the chip with a transparent lid. In another embodiment of the invention, the perimeter area of a chip, including interconnections such as wire bonds and bond pads, is encapsulated with a liquid dispensed epoxy, and a transparent lid is attached. In yet another embodiment of the invention, chip encapsulation is accomplished with a unitary shell of entirely transparent material. In yet another embodiment of the invention, a substrate-mounted chip and a transparent lid are loaded into a transfer mold that holds them in optimal alignment.

Abstract: A packaged assembly including an interposer or substrate supporting on a first side thereof a chip that is encased with an encapsulant is described. A second side of the interposer or substrate includes a barrier that blocks the flow of encapsulant to create a uniform encapsulant edge on the second side of the interposer. The uniform edge helps prevent flaking of the encapsulant off the interposer. The packaged assembly is adapted to be used with a further electronic device to expand the capablilities of the further electronic device.

Abstract: A method and apparatus for assembling and packaging semiconductor die assemblies utilizes a coating element such as a wafer backside laminate formed on a backside of a semiconductor die. The coating element may be formed from a somewhat compressible and, optionally, resilient material, which seals against a surface of a mold cavity while the semiconductor die assembly is being encapsulated. In this manner, the coating element prevents encapsulant material from covering at least a portion of the backside of the semiconductor die to prevent encapsulant flashing over the backside and thus improve heat dissipation characteristics of the packaged semiconductor die during operation.

Abstract: The present invention is directed toward methods and apparatuses for encapsulating a microelectronic die or another type of microelectronic device. One aspect of the present invention is directed toward packaging a microelectronic die that is attached to either a first surface or a second surface of a substrate. The die can be encapsulated by positioning the die in a cavity of a substrate and sealing the substrate to the substrate. The method can further include injecting an encapsulation compound into the cavity at a first end of the substrate to move along the first surface of the substrate. This portion of the compound defines a first flow of compound along the first surface that moves in a first direction from a first end of the substrate toward a second end of the substrate.

Abstract: A method and apparatus for encapsulating microelectronic devices. In one embodiment, a microelectronic device is engaged with a support member having a first edge, a second edge opposite the first edge, and an engaging surface with at least a portion of the engaging surface spaced apart from the first and second edges. The first edge of the support member is positioned proximate to a wall of a mold and an aligning member is moved relative to the wall of the mold to contact the engaging surface of the support member and bias the first edge of the support member against the wall of the mold. The microelectronic device is then encapsulated by disposing an encapsulating material in the mold adjacent to the microelectronic device. By biasing the first edge of the support member against the wall of the mold, the method can prevent encapsulating material from passing between the first edge of the support member and the wall of the mold, where the encapsulating material would otherwise form flash.