Abstract: A 4D device comprises a 2D multi-core logic and a 3D memory stack connected through the memory stack sidewall using a fine pitch T&J connection. The 3D memory in the stack is thinned from the original wafer thickness to no remaining Si. A tounge and groove device at the memory wafer top and bottom surfaces allows an accurate stack alignment. The memory stack also has micro-channels on the backside to allow fluid cooling. The memory stack is further diced at the fixed clock-cycle distance and is flipped on its side and re-assembled on to a template into a pseudo-wafer format. The top side wall of the assembly is polished and built with BEOL to fan-out and use the T&J fine pitch connection to join to the 2D logic wafer. The other side of the memory stack is polished, fanned-out, and bumped with C4 solder. The invention also comprises a process for manufacturing the device.

Abstract: The electrical characteristics of a semiconductor device are enhanced. In the package of the semiconductor device, there are encapsulated first and second semiconductor chips with a power MOS-FET formed therein and a third semiconductor chip with a control circuit for controlling their operation formed therein. The bonding pads for source electrode of the first semiconductor chip on the high side are electrically connected to a die pad through a metal plate. The bonding pad for source electrode of the second semiconductor chip on the low side is electrically connected to lead wiring through a metal plate. The metal plate includes a first portion in contact with the bonding pad of the second semiconductor chip, a second portion extended from a short side of the first portion to the lead wiring, and a third portion extended from a long side of the first portion to the lead wiring.

Abstract: An electronic module including a conductive-pattern layer; an insulating-material layer supporting the conductive-pattern layer; and at least one component inside the insulating-material layer is disclosed. The component includes a first surface and contact zones on the first surface. The electronic module further includes a first hardened adhesive layer on the first surface of the component; a second hardened adhesive layer in contact with the conductive-pattern layer and the first hardened adhesive layer; holes in the first and second hardened adhesive layer at the locations of the contact zones; and conductive material in the holes and in electrical connection with the contact zones of the component and the conductive-pattern layer.

Abstract: Provided is a stacked semiconductor package and a method of manufacturing the same. The stacked semiconductor package may include a first semiconductor package, a second semiconductor package, and at least one electrical connection device electrically connecting the first and second semiconductor packages. The first semiconductor package may include a first re-distribution pattern on a first semiconductor chip and a first sealing member on the first substrate, the first sealing member may include at least one first via to expose the first re-distribution pattern. The second semiconductor package may include a second re-distribution pattern on a second semiconductor chip and a second sealing member on a lower side of the second substrate, the second sealing member may include at least one second via to expose the second re-distribution pattern. An electrical connection device may be between the first and second vias to connect the first and the second re-distribution patterns.

Abstract: A stacked semiconductor package includes a substrate and a plurality of semiconductor dice stacked on the substrate. Each semiconductor die includes a recess, and a discrete component contained in the recess encapsulated in a die attach polymer. The stacked semiconductor package also includes interconnects electrically connecting the semiconductor dice and discrete components, and an encapsulant encapsulating the dice and the interconnects.

Abstract: System-in packages, or multichip modules, are described which can include multi-layer chips in a multi-layer polymer structure, on-chip metal bumps on the multi-layer chips, intra-chip metal bumps in the multi-layer polymer structure, and patterned metal layers in the multi-layer polymer structure. The multi-layer chips in the multi-layer polymer structure can be connected to each other or to an external circuit through the on-chip metal bumps, the intra-chip metal bumps and the patterned metal layers. The system-in packages can be connected to external circuits through solder bumps, meal bumps or wirebonded wires.

Abstract: In a through-via-hole path of semiconductor chips stacked in N stages, repeater circuits are provided in the respective semiconductor chips. For example, a signal transmitted from an output buffer circuit of the semiconductor chip is transmitted to an input buffer circuit of the semiconductor chip via the repeater circuits of the respective semiconductor chips. The respective repeater circuits can isolate impedances on input sides and output sides, and therefore, a deterioration of a waveform quality accompanied by a parasitic capacitance parasitic on the through-via-hole path of the respective semiconductor chips can be reduced and a high speed signal can be transmitted.

Abstract: A first semiconductor chip and a second semiconductor chip which form a stack are mounted on a module substrate by deflecting a center position of the semiconductor chips from the module substrate. In the side where the distance from the edge of the deflected semiconductor chip to the edge of a module substrate is shorter, the electrode pad on the first semiconductor chip and the electrode pad on the second semiconductor chip are directly connected with a wire. In the side where the distance from the edge of the deflected semiconductor chip to the edge of a module substrate is longer, the electrode pad on the first semiconductor chip and the electrode pad on the second semiconductor chip are combined with the corresponding bonding lead on the module substrate with a wire.

Abstract: An electronic module with switching functions includes integrated circuit chips arranged in a chip stack. The integrated circuit chips of the chip stack in each case includes a large-area contact on the top side and/or the rear side, the areal extent of the large-area contact completely occupies the top side and/or the rear side of the integrated circuit chip. A diffusion solder layer is arranged between mutually aligned large-area contacts of the stacked integrated circuit chips, the diffusion solder layer extending as far as the edges of the integrated circuit chips. A method for producing an electronic module with switching functions includes aligning and diffusion-soldering integrated circuit wafers with one another by their rear sides.

Abstract: A layered chip package includes a main body including a plurality of layer portions, and wiring disposed on a side surface of the main body. Each layer portion includes a semiconductor chip, an insulating portion covering at least one side surface of the semiconductor chip, and a plurality of electrodes connected to the semiconductor chip. The insulating portion has an end face located at the side surface of the main body on which the wiring is disposed. Each electrode has an end face surrounded by the insulating portion and located at the side surface of the main body on which the wiring is disposed.

Abstract: An integrated circuit (IC) package is disclosed. The IC package has an IC chip disposed on a top surface of a package substrate. Multiple solder balls are placed on the top surface of a package substrate, surrounding the IC chip. A molding compound covers the top surface area of the package substrate and surrounds the IC chip and each of the solder balls on the surface of the package substrate, leaving the top of each of the solder balls exposed. The embedded solder balls on the top surface of the package substrate may be used to connect the IC package to another IC package that may be placed directly on top of it. The solder balls may also be used to connect the IC package to another package substrate or an interposal substrate that may in turn be connected to another IC chip or package.

Abstract: A Chip-On-Lead (COL) type semiconductor package having small chip hidden between leads is revealed. The lower surfaces of the leadframe's leads are attached to a wiring substrate and the leads are horizontally bent to form a die-holding cavity. A smaller chip is disposed on the wiring substrate by passing through the die-holding cavity to be on the same disposing level with the leads. At least a larger chip is disposed on the leads to overlap the smaller chip so that the small chip does not extrude from the leads. The encapsulant encapsulates a plurality of internal parts of the leads, the wiring substrate, and the larger chip. Therefore, the conventional unbalance issue of mold flow above and below the leads leading to cause excessive warpage can be avoided and numbers of stacked larger chips can be increased to have larger memory capacities.

Abstract: The present invention provides an integrated circuit package system with die on base package comprising forming a base package comprising, forming a substrate, mounting a first integrated circuit on the substrate, encapsulating the integrated circuit and the substrate with a molding compound, and testing the base package, attaching a bare die to the base package, connecting electrically the bare die to the substrate and encapsulating the bare die and the base package.

Abstract: A semiconductor package including top-surface terminals for mounting another semiconductor package provides a three-dimensional circuit configuration that can provide removable connection of existing grid-array packages having a standard design. A semiconductor die is mounted on an electrically connected to a circuit substrate having terminals disposed on a bottom side for connection to an external system. The die and substrate are encapsulated and vias are laser-ablated or otherwise formed through the encapsulation to terminals on the top surface of the substrate that provide a grid array mounting lands to which another grid array semiconductor package may be mounted. The bottom side of the vias may terminate and electrically connect to terminals on the substrate, terminals on the bottom of the semiconductor package (through terminals) or terminals on the top of the semiconductor die.

Abstract: A semiconductor module includes: a substrate having a wiring layer; a first rectangular-shaped semiconductor device mounted on one surface of the substrate; a second rectangular-shaped semiconductor device mounted on the other surface of the substrate. The first semiconductor device is arranged such that each side thereof is not parallel to that of the second semiconductor device, and that the first semiconductor device is superimposed on the second semiconductor device, when seen from the direction perpendicular to the surface of the substrate.

Abstract: An integrated package system with die and package combination includes forming a leadframe having internal leads and external leads, encapsulating a first integrated circuit on the leadframe, and encapsulating a second integrated circuit over the first integrated circuit.

Abstract: A stackable multi-chip package system is provided including forming an external interconnect having a base and a tip, connecting a first integrated circuit die and the base, stacking a second integrated circuit die over the first integrated circuit die in an active side to active side configuration, connecting the second integrated circuit die and the base, and molding the first integrated circuit die, the second integrated circuit die, and the external interconnect partially exposed.

Abstract: In accordance with the present invention, there is provided multiple embodiments of a package-in-package semiconductor device including an RF package and a semiconductor die which are provided in a stacked arrangement and are each electrically connected to an underlying substrate through the use of conductive wires alone or in combination with conductive bumps. In certain embodiments of the present invention, the RF package and the semiconductor die are separated from each other by an intervening spacer which is fabricated from aluminum, or from silicon coated with aluminum. If included in the semiconductor device, the spacer is also electrically connected to the substrate, preferably through the use of conductive wires. The RF package, the semiconductor die, the spacer (if included) and a portion of the substrate are at least partially covered or encapsulated by a package body of the semiconductor device.

Abstract: A memory unit including a first transistor spanning a first transistor region in a first layer of the memory unit; a second transistor spanning a second transistor region in a second layer of the memory unit; a first resistive sense memory (RSM) cell spanning a first memory region in a third layer of the memory unit; and a second RSM cell spanning a second memory region in the third layer of the memory unit, wherein the first transistor is electrically coupled to the first RSM cell, and the second transistor is electrically coupled to the second RSM cell, wherein the second layer is between the first and third layers, wherein the first and second transistor have an transistor overlap region, and wherein the first memory region and the second memory region do not extend beyond the first transistor region and the second transistor region.

Abstract: A method for making an integrated circuit package-in-package system includes: forming a first integrated circuit package including a first device and a first substrate and having a first interface; stacking a second integrated circuit package including a second device and a second substrate and having a second interface above the first integrated circuit package; and fitting the first interface directly on the second interface.

Abstract: A semiconductor device is provided that includes a semiconductor chip and a resin section that molds the semiconductor chip and has a first through-hole. A through electrode that is electrically coupled to the semiconductor chip, extends through the resin section, and extends between a top edge and a bottom edge of an inner surface of the first through-hole. A cavity which extends between planes corresponding to an upper surface and a lower surface of the resin section is formed inside the first through-hole.

Abstract: A semiconductor package comprises a substrate having bond fingers on an upper surface thereof and ball lands on a lower surface thereof; at least two chip modules stacked on the upper surface of the substrate, each of the at least two chip modules including a plurality of semiconductor chips having first connection members and stacked in a manner such that the first connection members of the semiconductor chips are connected to one another, the chip modules being stacked in a zigzag pattern such that connection parts of the chip modules project sideward; and second connection members electrically connecting the connection parts of the respective chip modules to the bond fingers of the substrate.

Abstract: A stacked integrated circuit package system is provided forming a first stack layer having a first integrated circuit die on a first substrate, forming a second stack layer having a second integrated circuit die on a second substrate, and mechanically and electrically connecting a spacer layer having a first passive component between the second stack layer and the first stack layer.

Abstract: An integrated circuit package system comprising: providing a substrate; forming a base assembled package over the substrate; forming a top package over the base assemble package; and applying a top package stacking material for stand-off or insulation to the base assembled package and the top package.

Abstract: A method of manufacture of an integrated circuit package system includes: forming a base package including: fabricating a base package substrate having a component side and a system side, coupling a first integrated circuit die to the component side, and coupling stacking interconnects to the component side to surround the first integrated circuit die; forming a stacked integrated circuit package including: fabricating a stacked package substrate having a chip side, coupling a lower stacked integrated circuit die to the chip side, and attaching on a coupling side, of the stacked package substrate, the stacking interconnects; stacking the stacked integrated circuit package on the base package including the stacking interconnects of the stacked integrated circuit package on the stacking interconnects of the base package; and forming a stacked solder column by reflowing the stacked interconnects.

Abstract: In accordance with an aspect of the invention, a stacked microelectronic package is provided which may include a plurality of subassemblies, e.g., a first subassembly and a second subassembly underlying the first subassembly. A front face of the second subassembly may confront the rear face of the first subassembly. Each of the first and second subassemblies may include a plurality of front contacts exposed at the front face, at least one edge and a plurality of front traces extending about the respective at least one edge. The second subassembly may have a plurality of rear contacts exposed at the rear face. The second subassembly may also have a plurality of rear traces extending from the rear contacts about the at least one edge. The rear traces may extend to at least some of the plurality of front contacts of at least one of the first or second subassemblies.

Abstract: An integrated circuit package system provides a leadframe having a short lead finger and a long lead finger, and the long lead finger and the short lead finger reside substantially within the same horizontal plane. A first die is placed in the leadframe. A second die is offset from the first die. The offset second die is attached over the first die and the long lead finger with an adhesive. The first die is electrically connected to the short lead finger. The second die is electrically connected to at least the long lead finger or the short lead finger. At least portions of the leadframe, the first die, and the second die are encapsulated in an encapsulant.

Abstract: An integrated circuit package system comprising: providing an integrated circuit die having an active side; forming a first internal stacked module and a second internal stacked module over the active side of the integrated circuit die; and coupling an electrical interconnect between the first internal stacked module or the second internal stacked module and the active side.

Abstract: A stacked electronic component comprises a first electronic component adhered on a substrate via a first adhesive layer, and a second electronic component adhered by using a second adhesive layer thereon. The second adhesive layer has a two-layer structure formed by a same material and having different modulus of elasticity. The second adhesive layer of the two-layer structure has a first layer disposed at the first electronic component side and a second layer disposed at the second electronic component side. The first layer softens or melts at an adhesive temperature. The second layer maintains a layered shape at the adhesive temperature. According to the stacked electronic component, occurrences of an insulation failure and a short circuiting are prevented, and in addition, a peeling failure between the electronic components, an increase of a manufacturing cost, and so on, can be suppressed.

Abstract: A semiconductor device includes a first semiconductor layer and a first semiconductor element located in the first semiconductor layer. The semiconductor device also includes a second semiconductor layer of a transparent semiconductor material. The second semiconductor layer is disposed on the first semiconductor layer covering the first semiconductor element. The semiconductor device also includes a second semiconductor element located in the second semiconductor layer. The semiconductor device also includes a wire extending within the second semiconductor layer and electrically connecting the first and second semiconductor elements.

Abstract: Parasitic inductance of the main circuit of a power source unit is reduced. In a non-insulated DC-DC converter having a circuit in which a power MOSFET for high side switch and a power MOSFET for low side switch are connected in series, the power MOSFET for high side switch and the power MOSFET for low side switch are formed of n-channel vertical MOSFETs, and a source electrode of the power MOSFET for high side switch and a drain electrode of the power MOSFET for low side switch are electrically connected via the same die pad.

Abstract: A structure and a method for forming the same. The structure includes a substrate, a first interposer on the substrate, a second interposer on the substrate, and a first bridge. The first and second interposers are electrically connected to the substrate. The first bridge is electrically connected to the first and second interposers.

Abstract: A stacked semiconductor device includes a first semiconductor element bonded on a circuit base. The first semiconductor element is electrically connected to a connection part of the circuit base via a first bonding wire. A second semiconductor element is bonded on the first semiconductor element via a second adhesive layer with a thickness of 50 ?m or more. The second adhesive layer is formed of an insulating resin layer whose glass transition temperature is 135° C. or higher and whose coefficient of linear expansion at a temperature equal to or lower than the glass transition temperature is 100 ppm or less.

Abstract: A substrate includes a substrate; a number of pad redistribution chips stacked on the substrate and on one another after being rotated 90° in a predetermined direction relative to one another, the pad redistribution chips having a number of center pads positioned at the center thereof, a number of (+) edge pads positioned on an end thereof while corresponding to those of the center pads lying in (+) direction from a middle center pad located in the middle of the center pads, a number of (?) edge pads positioned on the other end thereof while corresponding to those of the center pads lying in (?) direction with symmetry to those of the center pads lying in the (+) direction, and a number of traces for electrically connecting the center pads to the corresponding (±) edge pads, respectively; a flexible PCB for electrically connecting the substrate to the pad redistribution chips; and an anisotropic dielectric film for electrically connecting the pad redistribution chips to the flexible PCB and the substrate to t

Abstract: A semiconductor package and a method for manufacturing the same is provided for minimizing or preventing warpage and twisting of semiconductor chip bodies as a result of thinning them during gringing. The semiconductor package includes a semiconductor chip body and a substrate. The semiconductor chip body has a first surface, a second surface facing away from the first surface, through-electrodes which pass through the semiconductor chip body and project from the second surface, and a warpage prevention part which projects in the shape of a fence along an edge of the second surface. The substrate has a substrate body and connection pads which are formed on an upper surface of the substrate body, facing the second surface, and which are connected with the projecting through-electrodes.

Abstract: An integrated circuit (IC) package with a plurality of chip capacitors placed on a surface of a die is disclosed. The chip capacitors may be placed on top of the die with an interposal substrate layer. Placing chip capacitors on top of the die may reduce the size of the packaging substrate required. One or more wires may be used to connect the chip capacitors on the interposal layer to the packaging substrate. The IC package may include a lid and a thermal interface material (TIM) placed on top of the die. The lid may be shaped such that a protruding portion of the lid contacts the die directly through the TIM to improve heat dissipation.

Abstract: A chip package comprises a first chip having a first side and a second side, wherein said first chip comprises a first pad, a first trace, a second pad and a first passivation layer at said first side thereof, an opening in said first passivation layer exposing said first pad, said first trace being over said first passivation layer, said first trace connecting said first pad to said second pad; a second chip having a first side and a second side, wherein said second chip comprises a first pad at said first side thereof, wherein said second side of said second chip is joined with said second side of side first chip; a substrate joined with said first side of said first chip or with said first side of said second chip; a first wirebonding wire connecting said second pad of said first chip and said substrate; and a second wirebonding wire connecting said first pad of said second chip and said substrate.

Abstract: Methods of forming a microelectronic packaging structure and associated structures formed thereby are described. Those methods may include forming a cavity in a plating material to hold a die, attaching the die in the cavity, forming a dielectric material adjacent the die, forming vias in the dielectric material adjacent the die, forming PoP lands in the vias, forming interconnects in the vias, and then removing the plating material to expose the PoP lands and die, wherein the die is disposed above the PoP lands.

Abstract: A stackable package substrate has an opening shaped and dimensioned to accommodate but not contact a mold cap of a package upon which the stackable package is to be mounted. On the die attach surface, the frame substrate accommodates a die attach margin adjacent at the edge of the opening; and a row of wire bond sites arranged along at an outer frame edge, for electrical interconnection. The frame substrate accommodates z-interconnect ball pads arranged to align with corresponding z-interconnect pads on the substrate of a package. A stackable package has a frame substrate. A stacked package assembly includes a second package mounted on a first package using peripheral solder ball z-interconnect, in which the first package includes a die enclosed by a mold cap and in which the second package includes one die mounted on the frame substrate.

Abstract: A semiconductor package includes a substrate having contacts, and a discrete component on the substrate in electrical communication with the contacts. The package also includes a semiconductor die on the substrate in electrical communication with the contacts, and a die attach polymer attaching the die to the substrate. The die includes a recess, and the discrete component is contained in the recess encapsulated in the die attach polymer. A method for fabricating the package includes the steps of: attaching the discrete component to the substrate, placing the die attach polymer on the discrete component and the substrate, pressing the die into the die attach polymer to encapsulate the discrete component in the recess and attach the die to the substrate, and then placing the die in electrical communication with the discrete component. An electronic system includes the semiconductor package mounted to a system substrate.

Abstract: One or more electronic components can be mounted on the back side of a semiconductor die. The components can be passive components, active components, or combinations thereof. The components can be soldered to signal routes on the back side of the die, the signal routes being attached to the die using a metallization layer or using one or more dielectric layer sections. Placing components on the back side of the die can allow for incorporation of the components without necessarily increasing the form factor of the die's package.

Abstract: An interconnect assembly for use in high frequency applications includes an interconnect structure, a plurality of electronic die disposed on the interconnect structure, and an encapsulant at least partially surrounding the plurality of electronic die. The interconnect structure includes a plurality of layers. The interconnect assembly further includes a thermal management layer disposed within a portion of the encapsulant and proximate to the plurality of electronic die and a controlled impedance interconnect connected to the interconnect structure and extending to a peripheral surface of the interconnect assembly.

Abstract: A three-dimensional package includes a carrier, a first die mounted on a first surface of the carrier, and a second die stacked on the first die. The first die includes first bond pads and second bond pads juxtaposed in separate two rows within a central region of the first die. The package further includes first bond fingers disposed on the first surface along a first side of the carrier, and second bond fingers along a second side opposite to the first side. A first bond wire is bonded to one of the first bond pads and extends to one the first bond fingers. The first bond wire overlies the row of the second bond pads. A second bond wire is bonded to one of the second bond pads and extends to one the second bond fingers. The second bond wire overlies the row of the first bond pads.

Abstract: A semiconductor die has devices such as MOSgated devices, diodes and the like formed into the top and bottom surfaces of the die. One terminal of each of the devices terminal in the interior center of the die and a common contact is made to the interior center of the die at one edge of the die. Various packages for the die having a reduced foot print on a support substrate are disclosed.

Abstract: A method of making 3D integrated circuits and a 3D integrated circuit structure. There is a first semiconductor structure joined to a second semiconductor structure. Each semiconductor structure includes a semiconductor wafer, a front end of the line (FEOL) wiring on the semiconductor wafer, a back end of the line (BEOL) wiring on the FEOL wiring, an insulator layer on the BEOL wiring and a metallic layer on the insulator layer. The first semiconductor structure is aligned with the second semiconductor structure such that the metallic layers of each of the semiconductor structures face each other. The metallic layers of each of the semiconductor structures are in contact with and bonded to each other by a metal to metal bond wherein the bonded metallic layers form an electrically isolated layer.

Abstract: Some embodiments of the invention provide a programmable system in package (“PSiP”). The PSiP includes a single IC housing, a substrate and several IC's that are arranged within the single IC housing. At least one of the IC's is a configurable IC. In some embodiments, the configurable IC is a reconfigurable IC that can reconfigure more than once during run time. In some of these embodiments, the reconfigurable IC can be reconfigured at a first clock rate that is faster (i.e., larger) than the clock rates of one or more of the other IC's in the PSiP. The first clock rate is faster than the clock rate of all of the other IC's in the PSiP in some embodiments.

Abstract: Method and apparatus for constructing and operating a high bandwidth package in an electronic device, such as a data storage device. In some embodiments, a high bandwidth package comprises a first known good die that has channel functions, a second known good die that has a controller function, and a third known good die that has a buffer function. Further in some embodiments, the high bandwidth package has pins that connect to each of the first, second, and third dies.

Abstract: The electrical characteristics of a semiconductor device are enhanced. In the package of the semiconductor device, there are encapsulated first and second semiconductor chips with a power MOS-FET formed therein and a third semiconductor chip with a control circuit for controlling their operation formed therein. The bonding pads for source electrode of the first semiconductor chip on the high side are electrically connected to a die pad through a metal plate. The bonding pad for source electrode of the second semiconductor chip on the low side is electrically connected to lead wiring through a metal plate. The metal plate includes a first portion in contact with the bonding pad of the second semiconductor chip, a second portion extended from a short side of the first portion to the lead wiring, and a third portion extended from a long side of the first portion to the lead wiring.

Abstract: Semiconductor chip packages have die asymmetrically arranged on the respective substrates. Two such packages having complementary arrangements can be stacked, one inverted with respect to the other, such that the two die are situated side-by-side in the space between the two substrates. Also, multipackage modules include stacked packages, each having the die asymmetrically arranged on the substrate. Adjacent stacked packages have complementary asymmetrical arrangements of the die, and one package is inverted with respect to the other in the stack, such that the two die are situated side-by-side in the space between the two substrates. Also, methods are disclosed for making the packages and for making the stacked package modules.

Abstract: In a semiconductor device, a first semiconductor chip is stacked on a wiring substrate and has first electrode pads disposed at predetermined positions on an upper surface thereof. A second semiconductor chip is stacked on the first semiconductor chip through an insulating member in an offset manner so that the first electrode pads are exposed. Support members support a back surface of a protruding portion of the second semiconductor chip through the insulating member.