Abstract: A chip structure having a redistribution layer includes: a chip with electrode pads disposed on an active surface thereof; a first passivation layer formed on the active surface and the electrode pads; a redistribution layer formed on the first passivation layer and having a plurality of wiring units, wherein each of the wiring units has a conductive pad, a conductive via and a conductive trace connecting the conductive pad and the conductive via, the conductive trace having at least a first through opening for exposing a portion of the first passivation layer; and a second passivation layer disposed on the first passivation layer and the redistribution layer, the second passivation layer being filled in the first through opening such that the first and second passivation layers are bonded to each other with the conductive trace sandwiched therebetween, thereby preventing delamination of the conductive trace from the second passivation layer.

Abstract: A chip structure and a stacked structure composed of the chip structures are provided. The chip structure has a substrate and at least one compliant contact. Furthermore, the chip structure may further have a redistribution layer for redistributing pads originally disposed around the substrate in a specific arrangement. The substrate has a first surface and a second surface. The compliant contact is embedded into the substrate and protrudes outside the first surface and the second surface of the substrate. The compliant contact has a compliant bump and a conductive layer encapsulating the compliant bump. The conductive layer can be connected with the redistribution layer. Two chip structures can be connected with each other through their compliant contacts or through their compliant contacts or redistribution layers.

Abstract: A 3D smart power module for power control, such as a three phase power control module, includes a two sided printed circuit (PC) board with power semiconductor devices attached to one side and control semiconductor devices attached to the other side. The power semiconductor devices are die bonded to a direct bonded copper substrate which has a bottom surface exposed in the molded package. In one embodiment the module has 27 external connectors attached to one side of the PC board and arranged in the form of a ball grid array.

Abstract: A semiconductor package includes a lead frame, a first chip, a second chip, a plurality of bonding wires and a mold compound. The lead frame includes a pad portion at a center of the frame and a plurality of lead portions. The pad portion and the plurality of lead portions collectively define a receiving portion. The first chip is securely received in the receiving portion. The second chip is mechanically attached to the first chip. The plurality of bonding wires electrically connect the second chip to the plurality of lead portions. The mold compound encapsulates the lead frame, the first chip, the second chip and the plurality of bonding wires to form the semiconductor package.

Abstract: A semiconductor device has a substrate and RF FEM formed over the substrate. The RF FEM includes an LC low-pass filter having an input coupled for receiving a transmit signal. A Tx/Rx switch has a first terminal coupled to an output of the LC filter. A diplexer has a first terminal coupled to a second terminal of the Tx/Rx switch and a second terminal for providing an RF signal. An IPD band-pass filter has an input coupled to a third terminal of the Tx/Rx switch and an output providing a receive signal. The LC filter includes conductive traces wound to exhibit inductive and mutual inductive properties and capacitors coupled to the conductive traces. The IPD filter includes conductive traces wound to exhibit inductive and mutual inductive properties and capacitors coupled to the conductive traces. The RF FEM substrate can be stacked over a semiconductor package containing an RF transceiver.

Abstract: A stacked chip package structure includes: a first chip and a second chip stacked on a substrate; a first electrical connection structure electrically connecting the substrate and the first chip; and a second electrical connection structure electrically connecting the second chip and the first chip, wherein the second electrical connection structure, disposed on a third chip, includes an adhesive layer encapsulating a second solder ball structure on the second chip and a first solder ball structure on the first chip; and a plurality of conductive wires disposed in the adhesive layer for conducting the second solder ball structure and the first solder ball structure. A fabrication method for the stacked chip package structure is also disclosed. Forming conductive wires in the adhesive layer electrically connecting the upper and lower chips may improve potential problems caused when using wire bonding technology for the upper chip during stacking of the multilayer chips.

Abstract: An integrated circuit packaging system including: connecting a first integrated circuit device and a package substrate; attaching a support bump to the package substrate; providing a second integrated circuit device having an inner encapsulation; applying a magnetic film on the inner encapsulation of the second integrated circuit device; and mounting the second integrated circuit device over the first integrated circuit device with the magnetic film on the first integrated circuit device and the support bump.

Abstract: A method of manufacture of a shielded stacked integrated circuit packaging system includes: forming a first integrated circuit structure having a first substrate and a first integrated circuit die; mounting a shield over the first substrate and the first integrated circuit die; mounting a second integrated circuit structure having a second substrate and a second integrated circuit die over the shield; and forming a package encapsulation for covering the first integrated circuit die, the shield, and the second integrated circuit structure.

Abstract: A semiconductor module according to the present invention includes: an insulating substrate (4); a plurality of semiconductor chips (1) disposed on a surface of the insulating substrate (4) so as to be apart from each other; solder layers (9) formed, on a back surface side of the insulating substrate (4), only at positions corresponding to positions at which the respective semiconductor chips (1) are disposed; and a base plate (6) connected to the insulating substrate (4) through the solder layers (9).

Abstract: A semiconductor component and methods for manufacturing the semiconductor component that includes a monolithically integrated common mode choke. In accordance with embodiments, a transient voltage suppression device may be coupled to the monolithically integrated common mode choke.

Abstract: A semiconductor die includes a semiconductive substrate layer with first and second sides, a metal layer adjacent the second side of the semiconductive substrate layer, one or more active devices in an active layer on the first side of the semiconductive substrate layer; and a passive device in the metal layer in electrical communication with the active layer. The passive device can electrically couple to the active layer with through silicon vias (TSVs).

Abstract: Graphene-channel based devices and techniques for the fabrication thereof are provided. In one aspect, a semiconductor device includes a first wafer having at least one graphene channel formed on a first substrate, a first oxide layer surrounding the graphene channel and source and drain contacts to the graphene channel that extend through the first oxide layer; and a second wafer having a CMOS device layer formed in a second substrate, a second oxide layer surrounding the CMOS device layer and a plurality of contacts to the CMOS device layer that extend through the second oxide layer, the wafers being bonded together by way of an oxide-to-oxide bond between the oxide layers. One or more of the contacts to the CMOS device layer are in contact with the source and drain contacts. One or more other of the contacts to the CMOS device layer are gate contacts for the graphene channel.

Abstract: A power electronic device package comprising a base member, a device layer, multiple leads, and an encapsulant is provided. The base member is thermally conductive for heat dissipation. The device layer comprises one or more power electronic devices mounted on the base member. The power electronic devices are selectively electrically connected to each other and to the base member to form an internal electronic circuit. The leads extend outwardly from the base member and are electrically connected to the internal electronic circuit. The encapsulant encases the internal electronic circuit, a portion of the base member, and a portion of the leads. The power electronic device package is configured as a transfer molded power module with multiple leads and increased power handling capability. In an embodiment, the base member is electrically conductive to operate as an electrical terminal. The base member may also be isolatably connected to the internal electronic circuit.

Abstract: A method for assembling die packages includes attaching contacts on a first side of a plurality of first die to substrate pads on a top surface of a composite carrier. The composite carrier includes a package substrate including at least one embedded metal layer having its bottom surface secured to a semiconductor wafer. The composite carrier minimizes effects of the CTE mismatch between the die and the package substrate during assembly reduces warpage of the die. After the attaching, the semiconductor wafer is removed from the package substrate. Electrically conductive connectors are attached to the bottom surface of the package substrate, and the package substrate is sawed to form a plurality of singulated die packages.

Abstract: A finger sensing device may include a mounting substrate, an integrated circuit (IC) die carried by the mounting substrate and having an array of electric field-based finger sensing elements, and first electrical connections coupling the mounting substrate and the IC die. In addition, the finger sensing device may include a protective plate attached over the array of electric field-based finger sensing elements and having a dielectric constant greater than 5 in all directions and a thickness greater than 40 microns to define a capacitive lens for the array of electric field-based finger sensing elements. The finger sensing device may also include an encapsulating material adjacent the mounting substrate and the IC die and around at least the first electrical connections.

Abstract: In a method for bonding semiconductor wafers of the present invention, a bonding layer containing a flux-active curing agent and a thermosetting resin is interposed between a first semiconductor wafer and a second semiconductor wafer, thereby producing a semiconductor wafer stacked body in which the first and second semiconductor wafers are stacked together, and then the semiconductor wafer stacked body is compressed in a thickness direction thereof while heating it so that the first and second semiconductor wafers are fixed together by melting and solidifying solder bumps while curing the thermosetting resin, thereby producing a semiconductor wafer bonded body in which first connector portions and second connector portions are electrically connected together through solidified products obtained by melting and solidifying the solder bumps.

Abstract: A semiconductor device has dual-molded semiconductor die mounted to opposite sides of a build-up interconnect structure. A first semiconductor die is mounted to a temporary carrier. A first encapsulant is deposited over the first semiconductor die and temporary carrier. The temporary carrier is removed. A first interconnect structure is formed over a first surface of the first encapsulant and first semiconductor die. The first interconnect structure is electrically connected to first contact pads of the first semiconductor die. A plurality of conductive pillars is formed over the first interconnect structure. A second semiconductor die is mounted between the conductive pillars to the first interconnect structure. A second encapsulant is deposited over the second semiconductor die. A second interconnect structure is formed over the second encapsulant. The second interconnect structure is electrically connected to the conductive pillars and first and second semiconductor die.

Abstract: A stacked integrated circuit (IC) may be manufactured with a second tier wafer bonded to a double-sided first tier wafer. The double-sided first tier wafer includes back-end-of-line (BEOL) layers on a front and a back side of the wafer. Extended contacts within the first tier wafer connect the front side and the back side BEOL layers. The extended contact extends through a junction of the first tier wafer. The second tier wafer couples to the front side of the first tier wafer through the extended contacts. Additional contacts couple devices within the first tier wafer to the front side BEOL layers. When double-sided wafers are used in stacked ICs, the height of the stacked ICs may be reduced. The stacked ICs may include wafers of identical functions or wafers of different functions.

Abstract: A semiconductor device includes at least one first component (5) (for example, a first integrated circuit), having a front face provided with electrical connection pads. The first component is embedded in a support layer (2) is a position such that the front face of the first component is not covered and lies parallel to a first face of the support layer. An intermediate layer (8) is formed on the front face of the first component and on the first face of the support layer. An electrical connection network (9) within the intermediate layer selectively connects to the electrical connection pads of the first component. The device further includes at least one second component (11) (for example, a second integrate circuit, having one face placed above the intermediate layer and provided with electrical connection pads selectively connected to the electrical connection network.

Abstract: A semiconductor package includes a semiconductor chip, an encapsulant embedding the semiconductor chip, first contact pads on a first main face of the semiconductor package and second contact pads on a second main face of the semiconductor package opposite to the first main face. The diameter d in micrometers of an exposed contact pad area of the second contact pads satisfies d?(8/25)x+142 ?m, wherein x is the pitch of the second contact pads in micrometers.

Abstract: A method for manufacturing an integrated circuit package system includes: providing a leadframe; forming a protruding pad on the leadframe; attaching a die to the leadframe; electrically connecting the die to the leadframe; and encapsulating at least portions of the leadframe, the protruding pad, and the die in an encapsulant.

Abstract: Signals are routed to and from identical stacked integrated circuit dies by selectively coupling first and second bonding pads on each of the dies to respective circuits fabricated on the dies through respective transistors. The transistors connected to the first bonding pads of an upper die are made conductive while the transistors connected to the second bonding pads of the upper die are made non-conductive. The transistors connected to the second bonding pads of a lower die are made conductive while the transistors connected to the first bonding pads of the lower die are made non-conductive. The second bonding pads of the upper die are connected to the second bonding pads of the lower die through wafer interconnects extending through the upper die. Signals are routed to and from the circuits on the first and second dies through the first and second bonding pads, respectively.

Abstract: An integrated circuit includes a core area. The core area has at least one edge region and a plurality of transistors disposed in the edge region. A plurality of dummy structures are disposed outside the core area and adjacent to the at least one edge region. Each channel of the transistors in a channel width direction faces at least one of the dummy structures.

Abstract: A method of forming through-hole vias in a semiconductor wafer involves forming a semiconductor wafer having a plurality of die with contact pads disposed on a surface of each die. The semiconductor wafer has a saw street between each die. A trench is formed in the saw street without using support material to support the semiconductor wafer. The trench extends only partially through the semiconductor wafer. The portion of the saw street below the trench along a backside of the semiconductor wafer has sufficient thickness to maintain structural support for the semiconductor wafer without support material during formation of conductive vias between the die, and electrically connection of the conductive vias to the contact pads. The portion of the saw street below the trench along the backside of the semiconductor wafer is removed. The semiconductor wafer is singulated along the saw street to separate the die.

Abstract: A method of forming through-hole vias in a semiconductor wafer involves forming a semiconductor wafer having a plurality of die with contact pads disposed on a surface of each die. The semiconductor wafer has a saw street between each die. A trench is cut in the saw street without using support material to support the wafer. The trench extends only partially through the wafer. The uncut portion of the saw street below the trench along a backside of the wafer providing structural support for the wafer without support material during formation a plurality of conductive vias in the saw streets adjacent to the contact pads, and electrical connection of the conductive vias to the contact pads. The uncut portion of the saw street below the trench along the backside of the wafer portion is removed. The semiconductor wafer is singulated along the saw street to separate the die.

Abstract: Fabricating an integrated circuit device includes providing a semiconductor substrate comprising a first surface and a second surface, forming a wiring layer on the first surface of the semiconductor substrate, providing a circuit chip, and arranging the circuit chip on the wiring layer of the semiconductor substrate. The fabricating further includes forming an embedding layer on the wiring layer and on the circuit chip, the embedding layer encapsulating the circuit chip, thinning the semiconductor substrate at the second surface after forming the embedding layer, and forming a conductive via in the semiconductor substrate being electrically coupled to the wiring layer and exposed at the second surface of the semiconductor substrate. Moreover, an integrated circuit device is described.

Abstract: An electronic package includes a first layer having a first surface, the first layer includes a first device having a first electrical node, and a first contact pad in electrical communication with the first electrical node and positioned within the first surface. The package includes a second layer having a second surface and a third surface, the second layer includes a first conductor positioned within the second surface and a second contact pad positioned within the third surface and in electrical communication with the first conductor. A first anisotropic conducting paste (ACP) is positioned between the first contact pad and the first conductor to electrically connect the first contact pad to the first conductor such that an electrical signal may pass therebetween.

Abstract: It is provided a contacting method when a plurality of films to be peeled are laminating. Reduction of total layout area, miniaturization of a module, weight reduction, thinning, narrowing a frame of a display device, or the like can be realized by sequentially laminating a plurality of films to be peeled which are once separately formed over a plastic film or the like. Moreover, reliable contact having high degree of freedom is realized by forming each layer having a connection face of a conductive material and by patterning with the use of a photomask having the same pattern.

Abstract: A semiconductor device is formed of two or more dice of similar dimensions and bond pad arrangements, in which bond pads are located in fields along less than three edges of the active surface of each die. A first die is attached to a substrate and subsequent die or dice are attached in a vertical sequence atop the first die, each in an offset configuration from the next lower die to expose the bond pads thereof for conductive bonding to metallization of the substrate. The multiple chip device permits a plurality of dice to be stacked in a high-density low-profile device. A particularly useful application is the formation of stacked mass storage flash memory package.

Abstract: A structure to prevent propagation of a crack into the active region of a 3D integrated circuit, such as a crack initiated by a flaw at the periphery of a thinned substrate layer or a bonding layer, and methods of forming the same is disclosed.

Abstract: A method of manufacturing a stacked semiconductor package using an improved technique of forming a through via in order to enable 3-dimensional vertical interconnection of stacked packages is provided. The method includes forming a seed layer required for forming a via core on a bottom surface of a wafer, forming at least one via hole vertically through the wafer, forming a via core in the via hole, insulating the via hole from the via core, and removing the seed layer from the bottom surface of the wafer. The stacked semiconductor package is suitable for high-speed signal transmission.

Abstract: Embodiments of the present disclosure provide a method comprising providing a semiconductor substrate having (i) a first surface and (ii) a second surface that is disposed opposite to the first surface, forming a dielectric film on the first surface of the semiconductor substrate, forming a redistribution layer on the dielectric film, electrically coupling one or more dies to the redistribution layer, forming a molding compound on the semiconductor substrate, recessing the second surface of the semiconductor substrate, forming one or more channels through the recessed second surface of the semiconductor substrate to expose the redistribution layer; and forming one or more package interconnect structures in the one or more channels, the one or more package interconnect structures being electrically coupled to the redistribution layer, the one or more package interconnect structures to route electrical signals of the one or more dies. Other embodiments may be described and/or claimed.

Abstract: a method for producing a semiconductor device provided in such a manner that a first layer and a second layer are laminated to ensure that their TSVs are arranged in almost a straight line, including: first layer production steps including steps of preparing a substrate, forming a transistor of an input/output circuit on an upper surface of the substrate, forming an insulation layer so as to cover the transistor, and forming a TSV in the insulation layer; second layer production steps including steps of preparing a substrate, forming a transistor of a logic circuit on an upper surface of the substrate, forming an insulation layer so as to cover the transistor, and forming a TSV in the insulation layer; a connection step of connecting surfaces of the first layer and the second layer on a side opposite to substrates of the first layer and the second layer to ensure that the TSV of the first layer and the TSV of the second layer are arranged in almost a straight line; and a step of removing the substrate of the

Abstract: In one embodiment, a method of forming a semiconductor device package includes: (1) providing a carrier and a semiconductor device including an active surface; (2) forming a first redistribution structure including a first electrical interconnect extending laterally within the first structure and a plurality of second electrical interconnects extending vertically from a first surface of the first interconnect, each second interconnect including a lower surface adjacent to the first surface and an upper surface opposite the lower surface; (3) disposing the device on the carrier such that the active surface is adjacent to the carrier; (4) disposing the first structure on the carrier such that the upper surface of each second interconnect is adjacent to the carrier, and the second interconnects are positioned around the device; and (5) forming a second redistribution structure adjacent to the active surface, and including a third electrical interconnect extending laterally within the second structure.

Abstract: In one embodiment, semiconductor die having non-rectangular shapes and die having various different shapes are formed and singulated from a semiconductor wafer.

Abstract: A lead frame assembly includes at least one die paddle. The die paddle includes a first landing area for receiving a first semiconductor chip and a second landing area for receiving a second semiconductor chip. One or more steps are provided between the first landing area and the second landing area.

Abstract: The degree of freedom of the chip layout in a semiconductor device is improved, and improvement in packaging density is aimed at. Since it becomes possible to form the wire of two directions on the pad of a memory chip by performing the over-bonding of reverse bonding by ball bonding, an effect equivalent to continuation stitch bonding of wedge bonding can be produced by ball bonding. Hereby, the degree of freedom of a chip layout and the degree of freedom of the lead layout of substrate 3 can be improved, and the packaging density on a substrate in a chip lamination type semiconductor device (memory card) can be improved.

Abstract: A method for manufacturing chip stack packages may include: providing at least two wafers, each wafer having a plurality of chips, and scribe lanes formed between and separating adjacent chips; forming a plurality of via holes in peripheral portions of the scribe lanes; forming connection vias by filling the via holes; establishing electrical connections between the chip pads and corresponding connection vias; removing material from the back sides of the wafers to form thinned wafers; separating the thinned wafers into individual chips by removing a central portion of each scribe lane; attaching a first plurality of individual chips to a test wafer; attaching a second plurality of individual chips to the first plurality of individual chips to form a plurality of chip stack structures; encapsulating the plurality of chip stack structures; and separating the plurality of chip stack structures to form individual chip stack packages.

Abstract: Quad Flat No-Lead packaged devices are manufactured using two singulation operations with two different saw blades of varying widths with the first singulation operation using a wider saw blade than the second singulation operation. Between singulation operations, the exposed portions of the leads are plated with a solderable metal. By performing the second singulation operation within the first cut made by the first singulation, at least half of the exposed metal of the leads remains plated. Thus, better solder joints may be formed, which allows for simpler visual inspection.

Abstract: Disclosed are packages for optocouplers and methods of making the same. An exemplary optocoupler comprises a substrate having a first surface and a second surface, a plurality of optoelectronic dice for one or more optocouplers disposed on the substrate's first surface, and a plurality of optoelectronic dice for one or more optocouplers disposed on the substrate's second surface. The substrate may comprise a pre-molded leadframe, and electrical connections between optoelectronic dice on opposite surfaces of the substrate may be made via one or more leads of the leadframe.

Abstract: A semiconductor device comprising a first semiconductor section including a first wiring layer at one side thereof, a second semiconductor section including a second wiring layer at one side thereof, the first and second semiconductor sections being secured together with the respective first and second wiring layer sides of the first and second semiconductor sections facing each other, a conductive material extending through the first semiconductor section to the second wiring layer of the second semiconductor section and by means of which the first and second wiring layers are in electrical communication.

Abstract: A method of assembling a multi-die package is achieved. A heat spreader is disposed on a printed circuit substrate. At least one integrated circuit die is disposed on a top side of the heat spreader and at least one other integrated circuit die is disposed on a bottom side of the heat spreader wherein the dies are connected to the substrate by wire bonds. Thermal solder balls are electrically connected to solderable pads of the heat spreader through the open holes of the substrate, so as to couple the heat spreader to function as a ground plane. Some of the ground pads of the dies can be bonded onto the heat spreader and the others bonded onto the substrate. Alternatively, all of the dies could only be connected to the substrate by wire bonding, and not connected to the heat spreader.

Abstract: A semiconductor chip stack includes a first chip and a second chip. The first chip includes a first circuit formed in the first chip with a first integration density, and the second chip includes a second circuit in the second chip with a second integration density smaller than the first integration density. The first chip further includes at least a through-silicon via formed therein for electrically connecting the first chip and the second chip.

Abstract: A method of mounting a first integrated circuit (102, 500, 704) on one of a circuit board (300, 700) or a second integrated circuit (706), the first integrated circuit (102, 500, 704) formed over a substrate (104) and having a surface (119) opposed to the substrate (104) and a side (122, 530, 930) substantially orthogonal to the surface (119), and including a conductive element (116, 117, 118, 522, 524, 526, 528, 528?, 528?) coupled to circuitry (102, 500, 704) and formed within a dielectric material (120, 518), the one of the circuit board (300, 700) or the second integrated circuit (706) including a contact point (304, 306, 314), the method including singulating (1104) the first integrated circuit (102, 500, 704) to expose the conductive element (116, 117, 118, 522, 524, 526, 528, 528?, 528?) on the side (222, 630, 1030), and mounting (1108) the first integrated circuit (102, 500, 704) on the one of a circuit board (300, 700) or a second integrated circuit (706) by aligning the conductive element (116, 117,

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing an integrated circuit with an adhesive attached thereto; connecting the integrated circuit and a plated interconnect pad; attaching an embedded interconnect to the plated interconnect pad; and forming an encapsulation, having an encapsulation first side and an encapsulation second side, around the integrated circuit, the embedded interconnect, and the plated interconnect pad with the embedded interconnect exposed from the encapsulation second side and the plated interconnect pad and the adhesive exposed from the encapsulation second side.

Abstract: An integrated circuit including: a first transistor; a second transistor, arranged on the first transistor, whereof a channel region is formed in a semiconductor layer including two approximately parallel primary faces; a portion of an electrically conductive material electrically connected to a gate of the first transistor and arranged between the gate of the first transistor and the channel region of the second transistor; a dielectric layer arranged between the portion of the electrically conductive material and the channel region of the second transistor; and in which the section of the channel region of the second transistor is included in the section of the portion of the electrically conductive material, and the channel region of the second transistor is arranged between the portion of the electrically conductive material and a gate of the second transistor.

Abstract: Several embodiments of microelectronic device packaging configurations with lead frames without downsets are disclosed herein. In one embodiment, the configuration includes a pair of microelectronic dies with active surfaces facing one another, and a lead frame positioned between the dies. The lead frame has no downset and extends from between the dies and protrudes out of an encapsulant material. In one embodiment the lead frame is connected to both an upper and a lower die. In other embodiments, the lead frame is connected to a first die by wirebonds and is not connected to a second die. The first and second die may be connected to one another by interconnects such as solder ball interconnects.

Abstract: A method of manufacture of an integrated circuit packaging system includes forming a lead frame including providing a tie bar plate, forming conductive columns on the tie bar plate, forming a dielectric layer on the conductive columns, applying a conductive shield layer on the dielectric layer, and exposing the conductive columns through the dielectric layer and the conductive shield layer; forming a base package substrate; mounting a base integrated circuit die on the base package substrate; mounting the tie bar plate, over the base integrated circuit die, conductively coupled to the base package substrate to form the conductive shield layer into an electro-magnetic interference shield; and removing the tie bar plate to expose the conductive columns from the dielectric layer.

Abstract: A package includes a printed circuit board (PCB) having a first side and a second side and a thickness between the first side and the second side and a stacked die including a top die mounted on a bottom die, the bottom die being at least partially embedded in the PCB. Also a method of forming a package that includes forming an opening in a top surface of the PCB layer, placing a stacked die including a top die stacked on a bottom die into the opening, laminating the PCB layer to form a laminate layer, and forming an electrical connection with the stacked die.

Abstract: An electronic package for containing at least a top packaging module vertically stacked on a bottom packaging module. Each of the packaging modules includes a semiconductor chip packaged and connected by via connectors and connectors disposed on a laminated board fabricated with a standard printed-circuit board process wherein the top and bottom packaging module further configured as a surface mountable modules for conveniently stacking and mounting to prearranged electrical contacts without using a leadframe. At least one of the top and bottom packaging modules is a multi-chip module (MCM) containing at least two semiconductor chips. At least one of the top and bottom packaging modules includes a ball grid array (BGA) for surface mounting onto the prearranged electrical contacts. At least one of the top and bottom packaging modules includes a plurality of solder bumps on one of the semiconductor chips for surface mounting onto the prearranged electrical contacts.