Abstract: The present invention discloses the structure and process for fabrication of an electronic package to contain and protect Package-to-Package (P2P) stacked module of integrated circuit (IC) chips. The process includes a step of providing an interposer that includes conductive traces interconnected between pre-designated contact pads disposed on a top and/or bottom surfaces for mounting at least a top or bottom packages of the IC chips with electric terminals contacting the contact pads disposed on the top and/or bottom surface of the interposer. Standoffs and passive components can also be added onto interposer in order to improve solder joints reliability, electrical performance and main board density at the same time. The inclusion of passive components on the interposer could enhance the electrical performance and the testability of the finished package stack.

Abstract: The present invention discloses an electronic package to contain and protect an integrated circuit (IC) chip. The electronic package further includes a leadframe, a flexible circuit or PCB type of substrate. The leadframe, flexible circuit or PCB type substrate further includes solder contacts, which are aligned with via holes in the molding layers on the top and bottom sides of the package. These via holes are for placing solder paste or solder balls from above and below for electrical access to the IC chip. These solder balls provide access for electrical testing after the package is mounted on a motherboard. They also provide the connection points for stacking multiple packages vertically.

Abstract: The present invention includes a chip-embedded support-frame wrapped-by-flex-circuit package assembly. The package assembly includes a flex circuit having a plurality of patterned connecting-traces. The package assembly further includes a plurality of semiconductor chips mounted on the flex circuits wherein the semiconductor chips having a plurality of contact terminals connected to corresponding connecting traces on the flex circuit. The package assembly further includes a support frame-board having an edge surface placed along predefined folded lines on the flex circuit. The frame-board has a plurality of open spaces for disposing each of the semiconductor chips therein. The flex circuit is provided for folding onto the support frame along the predefined folded lines to form the chip-embedded support-frame wrapped-by-flex-circuit package.

Abstract: The present invention discloses an electronic package to contain and protect an integrated circuit (IC) chip. The electronic package further includes a leadframe, a flexible circuit or PCB type of substrate. The leadframe, flexible circuit or PCB type substrate further includes solder contacts, which are aligned with via holes in the molding layers on the top and bottom sides of the package. These via holes are for placing solder paste or solder balls from above and below for electrical access to the IC chip. These solder balls provide access for electrical testing after the package is mounted on a motherboard. They also provide the connection points for stacking multiple packages vertically.

Abstract: A method for forming an integrated circuit interconnect pad is described. In one embodiment a method of forming an integrated circuit comprises screen printing a conductive paste onto a terminal metalization pad and curing the conductive paste in an inert or reducing atmosphere at an elevated temperature to form an under-bump metalization layer of an interconnect pad. The elevated temperature is below a melting temperature of the terminal metalization pad.

Abstract: The present invention provides a solution to the problem of weakening bond integrity in integrated circuit devices due in part to test probes galling and weakening the interconnect pads during functional and reliability test probing. In doing so, the invention enables a lowering of the chance a bond wire or interconnect pad will be lifted during a wire bonding process or in normal operation of an integrated circuit device.

Abstract: The present invention discloses a method for mounting multiple integrated circuit (IC) chips on a top surface of a substrate. The method includes a step forming a first footprint to include a plurality of electrical contacts on the top surface for mounting a first IC chip thereon. The method further includes a step of forming a set of substrate testing footprints to include a plurality of package mounting and testing electrical contacts for temporarily mounting a plurality of testing packages to conduct a functional MCM test. The functional MCM test is to test the substrate mounted with the first IC chip and the testing packages.

Abstract: The present invention provides a solution to the problem of weakening bond integrity in integrated circuit devices due in part to test probes galling and weakening the interconnect pads during functional and reliability test probing. In doing so, the invention enables a lowering of the chance a bond wire or interconnect pad will be lifted during a wire bonding process or in normal operation of an integrated circuit device.

Abstract: The present invention discloses an improved method for carry out a flip chip packaging process for attaching a semiconductor integrated circuit (IC) wafer having a plurality of input/output terminals, to a substrate. The method includes the steps of: 1) securely placing a plurality of solder balls on the substrate with each of said solder balls corresponding to a location of one of the input/output terminals on the integrated circuit wafer; 2) flipping the integrated circuit wafer for aligning each of the input/output terminals of the IC wafer to one of the solder balls; and 3) mounting the IC wafer onto the substrate for placing the I/O terminals on a corresponding solder ball and applying a reflow temperature for soldering the IC wafer to the substrate.

Abstract: The present invention discloses an improved method for carry out a flip chip packaging process for attaching a semiconductor integrated circuit (IC) wafer having a plurality of input/output terminals, to a substrate. The method includes the steps of: 1) securely placing a plurality of solder balls on the substrate with each of said solder balls corresponding to a location of one of the input/output terminals on the integrated circuit wafer; 2) flipping the integrated circuit wafer for aligning each of the input/output terminals of the IC wafer to one of the solder balls; and 3) mounting the IC wafer onto the substrate for placing the I/O terminals on a corresponding solder ball and applying a reflow temperature for soldering the IC wafer to the substrate.

Abstract: The present invention comprises a single-substrate multiple chip module (MCM) assembly. The MCM assembly includes a repair-package-site ready MCM board having a top surface and a bottom surface, the top surface further includes a plurality of chip connection trace lines include a chip-select line. The MCM assembly further includes a plurality of bare integrated circuit (IC) chips mounted directly on the top surface of the MCM board each chip connected to the plurality of chip connection trace lines on the top surface. The repair-package-site ready MCM board further includes at least a repair-package-site disposed on the bottom surface having a plurality of connection terminals arranged according to a standard repair packaged-chip footprint. Each of the connection terminals is connected to a via connector disposed in the MCM board for electrically connecting to the conductive trace lines on the top surface.

Abstract: The present invention includes an integrated multiple-substrate-on-chip-module (MSOCM) assembly. This assembly includes a chip-size package (CSP)-ready MSOCM board having a top surface and a bottom surface. The CSP-ready MCM board includes a plurality of bonding-wire windows and the bottom surface further includes a plurality of board bonding-pads near the bonding-wire window. The assembly further includes an adhesive layer disposed on top of the CSP-ready MCM board having also having a plurality of bonding wire windows corresponding to and aligned with the bonding wire windows on the MCM board. The assembly further includes a plurality of integrated circuit (IC) chips mounted onto the adhesive layer over the top surface of the CSP-ready MCM board. Each of the IC chips is provided with a plurality of chip bonding pads facing an open space defined by the bonding wire windows.

Abstract: The present invention discloses a face-to-face (FTF) stacked integrated circuit (IC) assembly. The FTF stacked IC assembly includes a first and a second substrate-on-bare-chip (SOBC) modules. Each of the first and second SOBC modules includes a printed circuit board (PCB) having a PCB bottom surface overlying an active circuit surface of a bare integrated circuit (IC) chip. The PCB includes a window opened substantially in a central portion of the active circuit surface of the bare IC chip. The bare IC chip includes bare-chip bonding-pads disposed on the active circuit surface in the window and the PCB includes a plurality of PCB bonding pads. Each of the first and second SOBC modules includes a plurality of bonding wires interconnecting the bare-chip bonding pads to the PCB bonding pads. Each of the first and second SOBC modules includes a plurality of solder balls disposed on a PCB top surface of the PCB connected to the PCB bonding pads with a plurality of metal traces disposed on the PCB board.

Abstract: The present invention discloses a chip-size package (CSP) ready multiple chip module (MCM) board having a top surface and a bottom surface for mounting and packaging a plurality of integrated circuit (IC) chips on the top surface. The MCM board is provided with a plurality of chip connection terminals on the top surface for electrically connecting to the IC chips. The MCM board further includes a plurality of via connectors in electrical connection with each of the MCM connection terminals. The MCM board further includes a plurality of CSP connection terminals disposed on the bottom surface substantially under the IC chips wherein each of the via connectors penetrating the MCM board for electrically connecting the CSP connection terminals to the MCM connection terminals.

Abstract: A semiconductor die (14) is mounted over a power supply surface (24, 52, 62). Signal bonding pads (18) on the die are wire bonded to corresponding leads (38) of a leadframe. Power supply bonding pads (20, 21) on the die are wire bonded to the power supply surface. A package body (22, 42, 56) surrounds the semiconductor die, the wire bonds (32, 34, 40, 40'), and the power supply surface. The power supply pad terminals are accessible from the bottom of the package body of the device through a plurality of conductive apertures (28, 56) disposed in the lower half of the package body. Power supply solder bumps (12, 58) are connected to the power supply surface inside the package body through the conductive apertures. The leads are used provide input and out signals for the device around the periphery of the device, while the solder bumps are disposed in an array format on the package body.

Abstract: A ball grid array semiconductor device (10) includes a package substrate (14 or 16) having a plurality of conductive traces (18), bond posts (20), and conductive vias (22). A semiconductor die (12) is mounted to the package substrate. Orthogonal wire bonds (28) are used to electrically connect staggered bond pads (26) to corresponding bond posts (20) on the substrate. A liquid encapsulant (40) is used to cover the die, the wire bonds, and portions of the package substrate. In another embodiment, a package substrate (50) includes a lower bonding tier (52) and an upper bonding tier (54). Wire bonds (60) are used to electrically connect an outer row of bond pads (64) to bond posts (20) of lower tier (52), while wire bonds (62) are used to electrically connect an inner row of bond pads (64) to bond posts (20) of an upper tier (54). The loop height of wire bonds (60) is smaller than that of wire bonds (62).

Abstract: A thermally enhanced semiconductor device (10) having an exposed backside (22) is described. In one embodiment, a PC board substrate (12) is provided having a pattern of conductive traces (14) on both upper and lower surfaces of the substrate. Electrical continuity is maintained between the two surfaces with conductive vias (16). A semiconductor die (18) is flip-mounted to the upper surface of the substrate. Solder bumps (26) electrically connect the die to the conductive traces, and an underfill (28) couples the active side (20) of the die to the upper surface of the substrate. A package body (40) is formed around the perimeter (24) of the die leaving the inactive backside exposed for enhanced thermal dissipation. The inactive backside can also be coupled to a heat sink for increased thermal dissipation. A plurality of solder balls (42) electrically connected to the conductive traces is attached to the lower surface of the substrate.

Abstract: A semiconductor (30) is shielded from electromagnetic interference by a combination of a reference plane (22) of a circuitized substrate (12) and two different encapsulants. The first encapsulant (38) is an electrically insulative encapsulant which mechanically protects a semiconductor die (32). The first encapsulant is constrained by a dam structure (40) so as not to encapsulate conductive reference pads (18) which are electrically connected to the reference plane by conductive vias (20). A second encapsulant (42) is dispensed over the first encapsulant and is in contact with the reference pads. The second encapsulant is an electrically conductive encapsulant, and is preferably made of a precursor material having the same or similar properties as that of the first encapsulant, but is filled with conductive filler particles to establish electrical conductivity of the encapsulant.

Abstract: A quad leadframe (22') for a CERQUAD is manufactured using conventional cladding and stamping technologies. A first metal layer (12) is provided with multiple cavities (14). A second metal layer (14) is clad to the first metal layer. A leadframe strip (22) can then be stamped from the clad metal. The leadframe has a leads (24) and bonding posts (28). The leads comprise two metal layers, and the bonding posts comprise only the second metal layer. The leadframe can then be used in the assembly of a semiconductor device (32). The portion of the leads external to the package body can be optionally etched to remove the second metal layer.

Abstract: An improved semiconductor device is disclosed having a predetermined amount of solder, or other electrically conductive binder adsorbed onto the exterior package leads of the semiconductor device. A de-wettable coating comprising preferably nickel, or alternatively chromium, is plated to a superior portion of the package leads, such that, when the heat is applied to the substrate mounting end of the leads, solder desorbes from the de-wettable layer and flows down the lead to the contact pads on the mounting substrate and forms a solder joint. The amount of solder delivered to the contact pad for joint formation is determined by the thickness of the adsorbed solder layer overlying each package lead. Only enough solder is provided on each lead sufficient to form the joint thus avoiding solder bridging between adjacent contact pads.