Abstract: This invention discloses a crystalline substrate based device including a crystalline substrate having formed thereon a microstructure; and at least one packaging layer which is sealed over the microstructure by means of an adhesive and defines therewith at least one gap between the crystalline substrate and the at least one packaging layer. A method of producing a crystalline substrate based device is also disclosed.

Abstract: A flip-bonded dual-substrate inductor includes a base substrate, a first inductor body portion provided on a surface of the base substrate, a cover substrate, a second inductor body portion provided on a surface of a cover substrate, and a nanoparticle bonding material provided between the base substrate surface and the cover substrate surface to electrically connect the first inductor body portion and the second inductor body portion. A method for fabricating a flip-bonded dual-substrate inductor including forming a first inductor body portion on a surface of a base substrate, forming a second inductor body portion on a surface of a cover substrate, and attaching the base substrate surface to the cover substrate surface using a nanoparticle bonding material that electrically connects the first inductor body portion and the second inductor body portion.

Abstract: A microelectronic package includes a first substrate (120) having a first surface area (125) and a second substrate (130) having a second surface area (135). The first substrate includes a first set of interconnects (126) having a first pitch (127) at a first surface (121) and a second set of interconnects (128) having a second pitch (129) at a second surface (222). The second substrate is coupled to the first substrate using the second set of interconnects and includes a third set of interconnects (236) having a third pitch (237) and internal electrically conductive layers (233, 234) connected to each other with a microvia (240). The first pitch is smaller than the second pitch, the second pitch is smaller than the third pitch, and the first surface area is smaller than the second surface area.

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: 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: An interposer includes a substrate, a conductive structure configured to contact the back side of a semiconductor device and contact pads. The interposer may include first and second sets of contact pads carried by the substrate. The interposer may also include conductive traces carried by the substrate to electrically connect corresponding contact pads of the first and second sets. The receptacles, which may be formed in a surface of the substrate and expose contacts of the second set, may be configured to at least partially receive conductive structures that are secured to the contact pads of the second set. Thus, the interposer may be useful in providing semiconductor device assemblies and packages of reduced height or profile. Such assemblies and packages are also described, as are multi-chip modules including such assemblies or packages.

Abstract: An assembly of substrate packages interconnected with flex cables and a method of fabrication of the substrate package. The assembly allows input/output (I/O) signals to be speedily transmitted between substrate packages via flex cable and without being routed through the motherboard. Embodiments relate to a substrate package providing separable inter-package flex cable connection. Hermetically-sealed guiding through holes are provided on the substrate package as a mechanical alignment feature to guide connection between flex cables and high speed I/O contact pads on the substrate package. Embodiments of the method of fabrication relate to simultaneously forming hermetically-sealed guiding through holes and I/O contact pads.

Abstract: An integrated circuit package-on-package stacking system includes a leadframe interposer including: a leadframe having a lead; a molded base on a portion of the lead for only supporting the lead; and the leadframe interposer singulated from the leadframe, wherein the lead is bent to support a stack-up height.

Abstract: In a stacked semiconductor package, since electric power is supplied to a second semiconductor package through a first semiconductor package, a power supply path becomes complicated and fluctuation of its inductance becomes large, whereby power bounce occurs to reduce signal quality and also prevent high speed signal communication. Therefore, according to the present invention, a first solder ball group for joint to a printed wiring board is attached to a second layer of the first semiconductor package, and a second solder ball group for joint to the first semiconductor package and a solder group for power supply for direct joint to the printed wiring board are provided on the second layer of the second semiconductor package, whereby electric power can be directly supplied from the printed wiring board.

Abstract: A method of fabricating a quad flat non-leaded package includes first forming a patterned conductive layer on a sacrificial layer. The patterned conductive layer includes a number of lead sets. A number of chips are attached to the sacrificial layer. Each of the chips is surrounded by one of the lead sets. Each of the chips is electrically connected to one of the lead sets, and a molding compound is formed on the sacrificial layer to cover the patterned conductive layer and the chips. The molding compound and the patterned conductive layer are then cut and singulated, and the sacrificial layer is pre-cut to form a number of recesses on the sacrificial layer. After the molding compound and the patterned conductive layer are cut and singulated and the sacrificial layer is pre-cut, the sacrificial layer is removed.

Abstract: A hosting structure of nanometric components is described advantageously comprising: a substrate; n array levels on said substrate, with n?2, arranged consecutively on growing and parallel planes, each including a plurality of conductive spacers alternated with a plurality of insulating spacers and substantially perpendicular to said substrate, with definition between consecutive conductive spacers of at least a gap, conductive spacers of consecutive array levels lying on distinct and parallel planes, said gaps of different array levels being at least partially aligned along a direction substantially perpendicular to said substrate with definition of a plurality of transversal hosting seats extended along said direction and suitable for hosting at least a nanometric component. A nanometric electronic device is also described comprising such a hosting structure and a method for realizing it.

Abstract: A portable memory card formed from a multi-die assembly, and methods of fabricating same, are disclosed. One such multi-die assembly includes an LGA SiP semiconductor package and a leadframe-based SMT package both affixed to a PCB. The multi-die assembly thus formed may be encased within a standard lid to form a completed portable memory card, such as a standard SD™ card. Test pads on the LGA SiP package, used for testing operation of the package after it is fabricated, may also be used for physically and electrically coupling the LGA SiP package to the PCB.

Abstract: A physically secure processing assembly is provided that includes dies mounted on a substrate so as to sandwich the electrical contacts of the dies between the dies and the substrate. The substrate is provided with substrate contacts and conductive pathways that are electrically coupled to the die contacts and extend through the substrate. Electrical conductors surround the conductive pathways. A monitoring circuit detects a break in continuity of one or more of the electrical conductors, and preferably renders the assembly inoperable. Preferably, an epoxy encapsulation is provided to prevent probing tools from being able to reach the die or substrate contacts.

Abstract: Computer modules with small thicknesses and associated methods of manufacturing are disclosed. In one embodiment, the computer modules can include a module substrate having a module material and an aperture extending at least partially into the module material. The computer modules can also include a microelectronic package carried by the module substrate. The microelectronic package includes a semiconductor die carried by a package substrate. At least a portion of the semiconductor die extends into the substrate material via the aperture.

Abstract: An integrated circuit package system including a substrate with a top surface and a bottom surface. Configuring the top surface to include electrical contacts formed between a perimeter of the substrate and a semiconductor die. Aligning over the top surface of the substrate a mold plate with a honeycomb meshwork of posts or a stepped honeycomb meshwork of posts and depositing a material to prevent warpage of the substrate between the top surface of the substrate and the mold plate. Removing the mold plate to reveal discrete hollow conduits formed within the material that align with the electrical contacts.

Abstract: An integrated circuit package-on-package stacking method includes forming a leadframe interposer including: forming a leadframe having a lead; forming a molded base only supporting the lead; and singulating the leadframe interposer from the leadframe.

Abstract: Corresponding parts to a first path portion in a first signal transmission path to a first semiconductor chip are an interconnection member and a second path portion a second signal transmission path to a second semiconductor chip and are not formed on the first tape. An electric length of the second signal transmission path is allowed to be adjusted independently of the first tape, so that the electric length of the second signal transmission path can be easily made equal to or substantially equal to that of the first signal transmission path.

Abstract: The point-to-point interconnection system for stacked devices includes a device, a substrate, operational circuitry, at least three electrical contacts and a conductor. The substrate has opposing first and second surfaces. A first electrical contact is mechanically coupled to the first surface of the device and electrically coupled to the operational circuitry. The second electrical contact is mechanically coupled to the first surface. The third electrical contact is mechanically coupled to the second surface opposite the first electrical contact. The conductor electrically couples the second electrical contact to the third electrical contact.

Abstract: The semiconductor module includes a plurality of memory die on a first side of a substrate and a plurality of buffer die on a second side of the substrate. Each of the memory die is disposed opposite and electrically coupled to one of the buffer die.

Abstract: A mountable integrated circuit package-in-package system is provided including mounting an adhesion spacer over an integrated circuit die and a package substrate, mounting an integrated circuit package system having an inner adhesion structure with the inner adhesion structure on the adhesion spacer, and forming a package encapsulation for covering the integrated circuit package system over the adhesion spacer.

Abstract: A connector includes a fitting hole into which a signal line is fitted, a tapered portion formed to lead a tip portion of the signal line to the fitting hole, and a bonded portion for bonding the connector to a control substrate. The tapered portion has a tapered shape on a side where the signal line is inserted. The tapered shape is tilted from a peripheral portion of the tapered portion to the fitting hole in a direction along which the signal line is inserted, with the fitting hole set as a center.

Abstract: An electronic component such as a semiconductor device is provided which is capable of preventing wiring breakage in a stress concentration region of surface layer wiring lines. In a semiconductor device provided with a support ball (5), no ordinary wiring line is formed in a region (7(A)) in the vicinity of the support ball (5) and a region (7(B)) at the end of the semiconductor chip facing the support ball (5), which are the stress concentration regions of the package substrate (2). Instead, a wiring line (6(C)) is formed away from these regions or a wide wiring line is formed in these regions.

Abstract: A method of fabricating a semiconductor die and a low profile semiconductor package are disclosed. The semiconductor package may include at least first and second stacked semiconductor die mounted to a substrate. The first and/or second semiconductor die may be fabricated with localized cavities through a bottom surface of the semiconductor die, along a side edge of the semiconductor die. The one or more localized cavities in a side take up less than the entire side. Thus, the localized cavities allow low height stacking of semiconductor die while providing each die with a high degree of structural integrity to prevent cracking or breaking of the die edge during fabrication.

Abstract: A semiconductor package can comprise a die stack attached to a substrate, with bond wires electrically connecting the two. Often multiple die stacks are adhered to a single substrate so that several semiconductor packages can be manufactured at once. A molding compound flow controller is optimally associated with the substrate or semiconductor package at one or more various locations. Flow controllers can control or direct the flow of the molding compound during the encapsulation process. Flow controllers can be sized, shaped, and positioned in order to smooth out the flow of the molding compound, such that the speed of the flow is substantially equivalent over areas of the substrate containing dies and over areas of the substrate without dies. In this manner, defects such as voids in the encapsulation, wire sweeping, and wire shorts can be substantially avoided during encapsulation.

Abstract: A semiconductor package comprises a base substrate with a semiconductor die mounted on a top side of the base substrate and an interposer substrate mounted on top of the die. The bottom side of the interposer substrate can be electrically coupled to the top side of the base substrate through vertical connectors. The top side of the interposer substrate is substantially exposed and comprises input/output (I/O) terminals for the mounting of additional electronic components. The base and interposer substrates can be configured with I/O terminals such that components mounted on the substrates can be electrically coupled through the vertical connectors. The base substrate also can be electrically coupled to an additional electronic component, such as a printed circuit board. Electrical connections can be “wrapped around” from the base substrate to the top of the interposer substrate.

Abstract: An aspect of the present invention features a manufacturing method of a package on package with a cavity. The method can comprise (a) forming a first upper substrate cavity in one side of an upper substrate; (b) mounting an upper semiconductor chip on the other side of the upper substrate; (c) forming a lower substrate cavity in one side of a lower substrate; (d) mounting a lower semiconductor chip in the lower substrate cavity formed in the lower substrate; and (e) stacking the upper substrate above the lower substrate such that the first upper substrate cavity accommodates a part of the lower semiconductor chip. The package on package and a manufacturing method thereof can reduce the overall thickness of the package by forming cavities in both upper and lower substrates to accommodate a semiconductor chip mounted in the lower substrate.

Abstract: A semiconductor device includes: a first semiconductor chip face-down mounted on a substrate; a second semiconductor chip face-up mounted on the first semiconductor chip; an electromagnetic shielding plate inserted between the first semiconductor chip and the second semiconductor chip; and a bonding wire bonded on the substrate so as to be astride of the electromagnetic shielding plate.

Abstract: In a stacked-type semiconductor device, a first semiconductor device and at least one second semiconductor device are stacked. The first semiconductor device includes a wiring board and a first semiconductor chip mounted on the wiring board. The second semiconductor device includes a wiring board and a second semiconductor chip mounted on the wiring board. The thickness of the second semiconductor chip of each second semiconductor device is thicker than the thickness of the first semiconductor chip.

Abstract: Provided is a semiconductor package accomplishing a fan-out structure through wire bonding in which a pad of a semiconductor chip is connected to a printed circuit board through wire bonding. A semiconductor package can be produced without a molding process and can be easily stacked on another semiconductor package while the appearance cracks and the warpage defects can be prevented.

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: A semiconductor device with a wiring substrate as a stacking element for a semiconductor device stack is described herein. The wiring substrate includes a plastic frame of a first plastic compound and a central region of a second plastic compound. A semiconductor chip is embedded with its back side and its edge sides in the second plastic compound, the active upper side of the semiconductor device being in a coplanar area with the first and second plastic compounds.

Abstract: An integrated circuit package-on-package stacking system is provided including, forming a leadframe interposer including: forming a leadframe; forming a molded base on the leadframe; and singulating the leadframe interposer from the leadframe.

Abstract: An offset integrated circuit package-on-package stacking system is provided including providing a base substrate, forming a contact pad on the base substrate, mounting a first integrated circuit on the base substrate, forming a base package body around the first integrated circuit, providing an offset substrate, mounting a second integrated circuit on the offset substrate, and coupling the offset substrate to the contact pad, including placing the offset substrate on the base package body.

Abstract: A stacked multi-chip package with an EMI shielded component has first and second substrates mounted together by a grid array of metallic connecting nodes, such as a solder Ball Grid Array. Each substrate has a conductive plane associated with it. An electronic component is mounted between the first and second substrates and is surrounded by a group of the metallic connecting nodes that are also electrically connected to the conductive planes of both substrates to form a conductive Faraday cage about the component.

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: SI in a semiconductor device in which a plurality of semiconductor chips differing in withstand voltage or in noise immunity, such as a multi-chip module, is to be improved. The semiconductor device comprises a first semiconductor chip and a second semiconductor chip mounted over a package substrate which has a plurality of bonding pads arranged along the edges. The first semiconductor chip has a plurality of bonding pads for analog signals, and the second semiconductor chip has a plurality of bonding pads for high-voltage signals. The edges along which the bonding pads for analog signals are arranged and the edges along which the bonding pads for high-voltage signals are arranged are disposed along mutually different edges of the package substrate. Adjoining of electrodes or wirings for high voltage signals and those for analog signals over the package substrate can be easily avoided, and SI deterioration can be thereby restrained.

Abstract: Provided are a layout of a semiconductor memory device capable of minimizing an occupation area of a dummy cell array and a method of controlling capacitance of a dummy cell to be same with that of the memory cell. The layout includes a dummy cell connected to one side of a sense amplifier, in which the dummy cell has a capacitance identical to a capacitance of the memory cell. The dummy cell is connected to one side of a sense amplifier connected to the memory cell and arranged in a column direction of the semiconductor substrate.

Abstract: A flex circuit is populated on one or both sides with plural integrated circuit die. In a preferred mode, the flex circuit is populated with flip-chip die. One side of the flex circuit has a connective facility implemented in a preferred mode with edge connector contacts. The flex circuit is disposed about a substrate to form a circuit module that may be inserted into an edge connector such as ones typically found on a computer board.

Abstract: After electrode pads 20 formed on a silicon substrate 1 and an electrode 21 to be connected thereto are exposed, a photoelectric conversion layer 12 is formed via a first mask 23 which covers exposed surfaces of the electrode pads 20 and the electrode 21. Then, a second electrode 13 is formed on a third electrode via a second mask 26 in which an opening is formed. This establishes a connection between the second electrode 13 and the electrode pads 20.

Abstract: An electronic component packaging structure, includes: circuit boards each having a wiring at least on a surface thereof; and an electronic component package secured between the circuit boards. The electronic component package includes at least one electronic component embedded within an electrical insulating encapsulation resin molded member made of an inorganic filler and a resin, the at least one electronic component being selected from an active component and a passive component, protruding electrodes are arranged on both faces of the electrical insulating encapsulation resin molded member, and the electronic component is connected electrically with at least a part of the protruding electrodes. This configuration allows circuit boards to be connected with each other and a high-density and high-performance structure.

Abstract: A memory chip package with a controller die on a first side of a printed circuit board and a memory die on a second side of the same printed circuit board. The memory chip package is integrated into a microprocessor controlled device or alternatively is integrated into a portable memory card.

Abstract: Ball grid array packages that can be stacked to form highly dense components and the method for stacking ball grid arrays are disclosed. The ball grid array packages comprise flexible or rigid substrates. The ball grid array packages additionally comprise an arrangement for the substantial matching of impedance for the circuits connected to the semiconductor devices.

Abstract: A multi-chip module has at least two semiconductor chips. Each of the semiconductor chips has chip electrodes of the semiconductor chip, electrically conductive interconnections for electrically connection with the chip electrodes, electrically conductive lands for electrically connection with the interconnections, external terminals placed on the lands, and a stress-relaxation layer intervening between the lands and the semiconductor chip. The semiconductor chips are placed on a mounting board via the external terminals. The distance between farthest ones of external terminal positioned at an outermost end portions of said second semiconductor chip is smaller than that of the first semiconductor chip.

Abstract: A three dimensional integrated circuit structure includes at least first and second devices, each device comprising a substrate and a device layer formed over the substrate, the first and second devices being bonded together in a stack, wherein the bond between the first and second devices comprises a metal-to-metal bond and a non-metal-to-non-metal bond.

Abstract: A COC DRAM including a plurality of stacked DRAM chips is mounted on a motherboard by using an interposer. The interposer includes a Si unit and a PCB. The Si unit includes a Si substrate and an insulating-layer unit in which wiring is installed. The PCB includes a reference plane for the wiring in the Si unit. The wiring topology between a chip set and the COC DRAM is the same for every signal. Accordingly, a memory system enabling a high-speed operation, low power consumption, and large capacity is provided.

Abstract: A flexible capacitive coupler assembly includes a flexible dielectric substrate assembly having a front surface and a rear surface, the front surface having thereon a macroscopic metal capacitive pad. A package supports the flexible dielectric substrate. An electrical connection is made to package wiring or leads on the flexible dielectric substrate to establish electrical contact with a computer subsystem.

Abstract: Corresponding parts to a first path portion in a first signal transmission path to a first semiconductor chip are an interconnection member and a second path portion a second signal transmission path to a second semiconductor chip and are not formed on the first tape. An electric length of the second signal transmission path is allowed to be adjusted independently of the first tape, so that the electric length of the second signal transmission path can be easily made equal to or substantially equal to that of the first signal transmission path.

Abstract: A semiconductor chip package may include a substrate, which may have bonding pads formed thereon. A semiconductor chip mounted on the substrate may have chip pads, and electrical connections for connecting the chip pads of the semiconductor chip to the substrate bonding pads. The semiconductor chip and the electrical connections on the substrate may be encapsulated, and a board attached to a portion of a surface of the substrate may not be encapsulated.

Abstract: Invertible microfeature device packages and associated methods for manufacture and use are disclosed. A package in accordance with one embodiment includes a microfeature device having a plurality of device contacts, and a conductive structure electrically connected to the contacts. The conductive structure can have first and second package contacts accessible for electrical coupling to at least one device external to the package, with the first package contacts accessible from a first direction and the second package contacts configured to receive solder balls and accessible from a second direction opposite the first. An encapsulant can be disposed adjacent to the microfeature device and the conductive structure and can have apertures aligned with the second package contacts to contain solder balls carried by the second package contacts.

Abstract: A semiconductor device comprising a semiconductor pellet mounted on a pellet mounting area of the main surface of a base substrate, in which first electrode pads arranged on the back of the base substrate are electrically connected to bonding pads arranged on the main surface of the semiconductor pellet. The base substrate is formed of a rigid substrate, and its first electrode pads are electrically connected to the second electrode pads arranged on its reverse side. The semiconductor pellet is mounted on the pellet mounting area of the main surface of the base substrate, with its main surface downward, and its bonding pads are connected electrically with the second electrode pads of the base substrate through bonding wires passing through slits formed in the base substrate.