Abstract: Various embodiments include apparatus and methods having circuitry to test continuity of conductive paths coupled to dice arranged in a stack. In at least one of these embodiments, a method includes electrically coupling each of the conductive paths to at least one of a first supply node and a second supply node. One of the conductive paths includes conductive material inside a via that can extend at least partly through a die among the dice in the stack. The method also includes receiving signals from the conductive paths, and determining continuity of the conductive paths based on the signals without using a boundary scan.

Abstract: An array of functional cells includes a subset of cells powered by at least one supply rail. That supply rail is formed of first segments located on a first metallization level and second segments located on a second metallization level with at least one conductor element extending between the first and second segments to electrically connect successive segments of the supply rail.

Abstract: A semiconductor device includes: at least one semiconductor element having electrode terminals; a metal plate supporting the semiconductor element; and a wiring board covering the semiconductor element and including a plurality of insulating layers and wiring layers alternately stacked and external connection terminals on a surface, the wiring layers being electrically connected to each other by vias. The electrode terminals and the external connection terminals are electrically connected via at least one of the wiring layers and the vias. At least one of the electrode terminals, the is wiring layers, and the vias is electrically connected to the metal plate.

Abstract: Provided is a wafer level packaging method and a semiconductor device fabricated using the same. In the method, a substrate comprising a plurality of chips is provided. An adhesive layer is formed on the substrate corresponding to boundaries of the plurality of chips. A cover plate covering an upper portion of the substrate and having at least one opening exposing the adhesive layer or the substrate at the boundaries among the plurality of chips is attached to the adhesive layer.

Abstract: A semiconductor device in which defects in characteristics due to electrostatic discharge is reduced and a method for manufacturing the semiconductor device are provided. The semiconductor device has at least one of these structures: (1) a structure in which a first and second insulating films are in direct contact with each other in a peripheral region of a circuit portion, (2) a structure in which a first and second insulators are closely attached to each other, and (3) a structure in which a first conductive layer and a second conductive layer are provided on outer surfaces of the first insulator and the second insulator, respectively, and electrical conduction between the first and second conductive layers is achieved at a side surface of the peripheral region. Note that the conduction at the side surface can be achieved by cutting a plurality of semiconductor devices into separate semiconductor devices.

Abstract: According to various aspects, exemplary embodiments are provided of thermal interface material assemblies. In one exemplary embodiment, a thermal interface material assembly generally includes a thermal interface material having a first side and a second side and a metallization layer having a layer thickness of about 0.0005 inches or less. The metallization layer is disposed along at least a portion of the first side of the thermal interface material.

Abstract: There has been very little (if any) attention to address contamination diffusion within an integrated circuit (IC) because there are very few applications where a protective overcoat will be penetrated as part of the manufacturing process. Here, a sealing ring is provided that address this problem. Preferably, the sealing ring uses the combination of electrically conductive barrier rings and the tortuous migration path to allow an electronic device (i.e., thermopile), where a protective overcoat is penetrated during manufacture, to communicate with external devices while being isolated to prevent contamination.

Abstract: A package substrate including an outermost interlayer resin insulating layer, a pad structure formed on the outermost interlayer resin insulating layer, a conductive connecting pin for establishing an electrical connection with another substrate, the conductive connecting pin being secured to the pad structure via a solder, and via holes formed through the outermost interlayer resin insulating layer and for electrically connecting the pad structure to one or more conductive circuits formed below the outermost interlayer resin insulating layer, the via holes being positioned directly below the pad structure.

Abstract: Provided are a printed circuit board (PCB) and a semiconductor package including the same. The PCB includes a core layer having a stacked structure including at least a first layer made of a first material that has a first coefficient of thermal expansion (CTE) and a second layer made of a second material that has a second CTE different from the first CTE, an upper wiring layer disposed on a first surface of the core layer, and a lower wiring layer disposed on a second surface of the core layer opposite the first surface.

Abstract: Of three chips (2A), (2B), and (2C) mounted on a main surface of a package substrate (1) in a multi-chip module (MCM), a chip (2A) with a DRAM formed thereon and a chip (2B) with a flash memory formed thereon are electrically connected to wiring lines (5) of the package substrate (1) through Au bumps (4), and a gap formed between main surfaces (lower surfaces) of the chips (2A), (2B) and a main surface of the package substrate (1) is filled with an under-fill resin (6). A chip (2C) with a high-speed microprocessor formed thereon is mounted over the two chips (2A) and (2B) and is electrically connected to bonding pads (9) of the package substrate (1) through Au wires (8).

Abstract: A semiconductor device, includes a chip, a first external terminal, a second external terminal, and a partial antenna wiring that is coupled to the first external terminal, and that constitutes a matching circuit, wherein the chip includes first and second electrode pads that are coupled to the partial antenna wiring, a third electrode pad that is different from each of the first and second electrode pads, and that is coupled to the second external terminal, and an electrostatic discharge (ESD) protection circuit that is coupled to the third electrode pad.

Abstract: A structure includes a hybrid substrate for supporting a semiconductive device that includes a bumpless build-up layer in which the semiconductive device is embedded and a laminated-core structure. The bumpless build-up layer and the laminated-core structure are rendered an integral apparatus by a reinforcement plating that connects to a plated through hole in the laminated-core structure and to a subsequent bond pad of the bumpless build-up layer structure.

Abstract: A microelectronic package including a dielectric layer having top and bottom surfaces, the dielectric layer having terminals exposed at the bottom surface; a metallic wall bonded to the dielectric layer and projecting upwardly from the top surface of the dielectric layer and surrounding a region of the top surface; a metallic lid bonded to the wall and extending over the region of the top surface so that the lid, the wall and the dielectric layer cooperatively define an enclosed space; and a microelectronic element disposed within the space and electrically connected to the terminals.

Abstract: A wiring substrate includes a wiring pattern in an uppermost layer that includes pads. A solder resist layer covers the wiring pattern. A recess exposes part of the wiring pattern from the solder resist layer to form pads. The solder resist layer includes a portion formed in a region corresponding to the recess, a portion formed outward from the recess, and a portion formed inward from the recess. The upper surface of the solder resist layer at the portion corresponding to the recess is higher than the upper surface of the pads but lower than the upper surfaces of the other portions of the solder resist layer.

Abstract: A method of manufacture of a semiconductor packaging system includes: providing a base substrate having edges; mounting an electrical interconnect on the base substrate; and applying an encapsulant having a reference marker and an opening over the electrical interconnect, the reference marker around the electrical interconnect based on physical locations of the edges.

Abstract: A semiconductor assembly is provided that includes a substrate. A first set of non-conductive hedges is disposed on and protrudes from a first surface of the substrate. A chip is coupled to and spaced apart from the substrate. The chip has a second surface facing the first surface of the substrate. A second set of non-conductive hedges is disposed on and protrudes from the second surface of the chip. The first set of hedges is configured and positioned to engage the second set of hedges to restrict movement of the substrate with respect to the chip. The second set of hedges is configured and positioned to engage the first set of hedges to restrict movement of the chip with respect to the substrate.

Abstract: An environment-resistant module which provides both thermal and vibration isolation for a packaged micromachined or MEMS device is disclosed. A microplatform and a support structure for the microplatform provide the thermal and vibration isolation. The package is both hermetic and vacuum compatible and provides vertical feedthroughs for signal transfer. A micromachined or MEMS device transfer method is also disclosed that can handle a wide variety of individual micromachined or MEMS dies or wafers, in either a hybrid or integrated fashion. The module simultaneously provides both thermal and vibration isolation for the MEMS device using the microplatform and the support structure which may be fabricated from a thin glass wafer that is patterned to create crab-leg shaped suspension tethers or beams.

Abstract: A method for producing a rollable web with successive antennas, where an electronic chip is attached to an antenna in a predetermined position. The position of an electronic chip changes with respect to the antenna when compared to at least some of the chips within individual and successive antennas. A rollable web includes successive antennas, where electronic chips are attached to antennas in a predetermined position. In the rollable web, the position of a chip changes with respect to the antenna compared to at least some of the chips within individual and successive antennas.

Abstract: A semiconductor device includes a substrate having a first side and a second side, the second side having a mounting location for at least one semiconductor element, and the first side having a plurality of locations electrically connected to locations on the second side. A plurality of electrically conductive interconnects are provided at the locations, each having a first end attached at the location and a second end spaced from the substrate, and an encapsulant partially encapsulates the plurality of interconnects and has a surface lying in a first plane. The second ends are located on the side of the first plane opposite from the substrate first side, an annular space in the encapsulant surrounds each of the plurality of electrically conductive interconnects, and the annular space has a bottom located between the first plane and the substrate first side. Also a method for making such a semiconductor device.

Abstract: A three-dimensional semiconductor module and an electronic system including the same are provided. The semiconductor module includes a module substrate, a logic device formed on a part of the module substrate, and a plurality of memory devices formed on another part of the module substrate, wherein the plurality of memory devices are disposed perpendicular to the logic device, and the module substrate on which the plurality of memory devices are formed is supported by a supporter. The electronic system includes the semiconductor module.

Abstract: A wiring substrate includes plural wiring layers and plural insulation layers being alternately stacked one on top of the other. The plural insulation layers are formed with insulation resin having the same composition. The plural insulation layers are formed with a filler having the same composition. The filler content of each of the plural insulation layers ranges from 30 vol % or more to 65 vol % or less. The thermal expansion coefficient of each of the plural insulation layers ranges from 12 ppm/° C. or more to 35 ppm/° C. or less.

Abstract: A semiconductor device includes an electronic component having an electrode pad provided on an electrode pad forming face, and a rear face positioned on a side opposite to the electrode pad forming face; an insulating member provided to seal a periphery of the electronic component, and having a first face exposing the electrode pad forming face of the electronic component and a second face exposing the rear face of the electronic component; a multi-layer wiring structure body provided to cover the first face of the insulating member, the electrode pad, and the electrode pad forming face, and including a plurality of insulating layers laminated on each other, and a wiring pattern; and a piercing electrode piercing the insulating member from the first face to the second face. The wiring pattern is directly connected to the electrode pad and the piercing electrode.

Abstract: A semiconductor device includes a multilayer wiring substrate and a double-sided multi-electrode chip. The double-sided multi-electrode chip includes a semiconductor chip and has multiple electrodes on both sides of the semiconductor chip. The double-sided multi-electrode chip is embedded in the multilayer wiring substrate in such a manner that the double-sided multi-electrode chip is not exposed outside the multilayer wiring substrate. The electrodes of the double-sided multi-electrode chip are connected to wiring layers of the multilayer wiring substrate.

Abstract: Methods and apparatus provide for: applying an inorganic barrier layer to at least a portion of a flexible substrate, the barrier layer being formed from a low liquidus temperature (LLT) material; and sintering the inorganic barrier layer while maintaining the flexible substrate below a critical temperature.

Abstract: A semiconductor device includes a semiconductor integrated circuit device (1). In the semiconductor integrated circuit device (1), a semiconductor integrated circuit (5) is formed on a center of the surface of a semiconductor substrate (3), and a plurality of electrode terminals (71, 73, . . . ) are provided on the surface of the semiconductor substrate (3). A protection film (9) is provided on the surface of the semiconductor substrate (3) such that the surfaces of the electrode terminals (71, 73) are exposed. The electrode terminals (71, 73, . . . ) include an electrode terminal (73) having a thin portion (74). The surface of the thin portion (74) is located below the surfaces of the electrode terminals except for the electrode terminal (73) having the thin portion (74) among the electrode terminals (71, 73, . . . ).

Abstract: In the laminated and sintered ceramic circuit board according to the present invention, at least a portion of the inplane conductor is fine-lined, such that the shape of the cross-section surface of the fine-lined inplane conductor is trapezoid, and the height (a), the length (c) of the lower base and the length (d) of the upper base of the trapezoidal cross-section surfaces, and the interval (b) between the lower bases of the trapezoidal cross-section surfaces of the inplane conductors adjacent in a plane parallel to the principal surfaces of the board meet a certain relation. This provides a laminated ceramic circuit board with low open failure rate, short-circuit failure rate and high reliability against high temperature and high humidity in a downsized and short-in-height (thin) semiconductor package.

Abstract: An integrated circuit packaging system and method of manufacture thereof includes: leads and a paddle; a first encapsulant molded between the leads and the paddle, the first encapsulant thinner than the leads; a non-conductive layer over the paddle; and conductive traces directly on the leads, the first encapsulant, and the non-conductive layer.

Abstract: The semiconductor device has insulating films 40, 42 formed over a substrate 10; an interconnection 58 buried in at least a surface side of the insulating films 40, 42; insulating films 60, 62 formed on the insulating film 42 and including a hole-shaped via-hole 60 and a groove-shaped via-hole 66a having a pattern bent at a right angle; and buried conductors 70, 72a buried in the hole-shaped via-hole 60 and the groove-shaped via-hole 66a. A groove-shaped via-hole 66a is formed to have a width which is smaller than a width of the hole-shaped via-hole 66. Defective filling of the buried conductor and the cracking of the inter-layer insulating film can be prevented. Steps on the conductor plug can be reduced. Accordingly, defective contact with the upper interconnection layer and the problems taking place in forming films can be prevented.

Abstract: A single metal layer tape substrate includes a patterned metal layer affixed to a patterned dielectric layer. The dielectric layer is patterned to provide openings exposing lands and bond sites on bond fingers on the land side of the metal layer. The metal layer is patterned to provide circuit traces as appropriate for interconnection with the die and with other elements. Interconnection with a die is made by wire bonding to exposed traces on a die attach side of the metal layer, and bond fingers and lands for access to testing the package are provided on the land side of the metal layer.

Abstract: A wiring electronic component of the present invention is incorporated into an electronic device package in which a circuit element including a semiconductor chip is disposed and in which the circuit element is connected to a wiring pattern on the back face and also connected, via vertical wiring, to external electrodes located on the front face opposite the wiring pattern. The wiring electronic component is composed of an electrically conductive support portion, which serves as an electroforming mother die, and a plurality of vertical wiring portions formed through electroforming such that they are integrally connected to the support portion.

Abstract: A substrate for suspension comprises a metallic substrate, an insulating layer formed on the metallic substrate, having an opening for grounding terminal, and a grounding conductor formed on the insulating layer. A grounding-terminal-forming material is placed in the opening for grounding terminal to form a grounding terminal that connects the metallic substrate and the grounding conductor. The grounding conductor does not surround a portion of the circumference of the opening for grounding terminal.

Abstract: A manufacturing method of a package structure is provided. A metal substrate is provided. The metal substrate has a first surface where a first seed layer is formed. A patterned insulating layer is formed on the first seed layer and exposes a portion of the first seed layer. A patterned circuit layer is formed on the exposed portion of the first seed layer and covers a portion of the patterned insulating layer. A chip-bonding process is performed to electrically connect a chip to the patterned circuit layer. An encapsulant encapsulating the chip and the patterned circuit layer and covering a portion of the pattered insulating layer is formed. The metal substrate and the first seed layer are removed to expose a bottom surface of the patterned insulating layer and a lower surface of the patterned circuit layer. Solder balls are formed on the lower surface of the patterned circuit layer.

Abstract: In inlets used for ID tags and the like, a defective connection between an integrated circuit part and an antenna is suppressed by improvement of tolerance for a bending or a pressing pressure. The integrated circuit part includes a semiconductor chip and a multilayer substrate having a concave portion. The semiconductor chip is mounted on the bottom of the concave portion. The multilayer substrate includes a connection electrode at the top surface and a connection electrode connected to the semiconductor chip on the bottom of the concave portion. The connection electrode on the bottom of the concave portion is connected to the connection electrode at the top surface by a penetration electrode inside a multilayer substrate. By such a configuration, the semiconductor chip is connected to the antenna.

Abstract: The present disclosure is directed to a semiconductor die having a chip outline boundary, a die seal, a row of input/output contact pads separated from the chip outline boundary by the die seal, a first row of solder bump connections positioned between the row of input/output contact pads and the die seal, and a second row of solder bump connections separated from the first row of solder bump connections by the row of input/output contact pads.

Abstract: A method for forming an interconnect structure with nanocolumnar intermetal dielectric is described involving the construction of an interconnect structure using a solid dielectric, and introducing a regular array of vertically aligned nanoscale pores through stencil formation and etching to form a hole array and subsequently pinching off the tops of the hole array with a cap dielectric. Variations of the method and means to construct a multilevel nanocolumnar interconnect structure are also described.

Abstract: A semiconductor device includes a SOI (silicon on insulator) substrate having a first region and a second region, a multilayer wiring layer formed on the SOI substrate and having an insulating layer and a wiring layer alternately stacked in this order, a first inductor formed over the SOI substrate, and a second inductor formed over the SOI substrate and positioned above the first inductor.

Abstract: A package enclosing at least one microelectronic element (60) such as a sensor die and having electrically conductive connection pads (31) for electric connection of the package to another device is manufactured by providing a sacrificial carrier; applying an electrically conductive pattern (30) to one side of the carrier; bending the carrier in order to create a shape of the carrier in which the carrier has an elevated portion and recessed portions; forming a body member (45) on the carrier at the side where the electrically conductive pattern (30) is present; removing the sacrificial carrier; and placing a microelectronic element (60) in a recess (47) which has been created in the body member (45) at the position where the elevated portion of the carrier has been, and connecting the microelectronic element (60) to the electrically conductive pattern (30). Furthermore, a hole (41) is arranged in the package for providing access to a sensitive surface of the microelectronic element (60).

Abstract: A leadframe package includes a die pad with four unitary, outwardly extending slender bars; a plurality of leads arranged along periphery of the die pad; a separate pad segment separated from the die pad and isolated from the plurality of leads; a semiconductor die mounted on an upper side of the die pad, wherein the semiconductor die contains first bond pads wire-bonded to respective the plurality of leads and a second bond pad wire-bonded to the separate pad segment; and a molding compound encapsulating the semiconductor die, the upper side of the die pad, the first suspended pad segment and inner portions of the plurality of leads.

Abstract: In accordance with one or more embodiments, a flange package comprises a flange and an interposer having two or more fingers disposed in an interposer trench. The flange has a mold lock formed about a periphery of the interposer trench. A dielectric ring comprising a dielectric material is formed in the interposer trench, and in and around the periphery of the mold lock. A semiconductor die is disposed within the dielectric ring having gate pads and source pads formed on a first side, and having drain pads disposed on a second side of the die. The gate pads are coupled to the interposer and the source pads are coupled to the flange. A gate lead is coupled to the interposer and a drain lead is coupled to the drain pads. Other embodiments are disclosed.

Abstract: A semiconductor device package is provided. The semiconductor device package includes a laminate comprising a first metal layer disposed on a dielectric film; a plurality of vias extending through the laminate according to a predetermined pattern; one or more semiconductor devices attached to the dielectric film such that the semiconductor device contacts one or more vias; a patterned interconnect layer disposed on dielectric film, said patterned interconnect layer comprising one or more patterned regions of the first metal layer and an electrically conductive layer, wherein a portion of the patterned interconnect layer extends through one or more vias to form an electrical contact with the semiconductor device. The patterned interconnect layer comprises a top interconnect region and a via interconnect region, wherein the package interconnect region has a thickness greater than a thickness of the via interconnect region.

Abstract: A process for assembling a package for a semiconductor device comprising reducing the stress in an inner dielectric layer during packaging by heating the die and the substrate to a temperature where a solder reflows, dropping to a temperature where a selected epoxy will cure, liquefying the epoxy, adding the liquefied epoxy to the die and substrate, and maintaining the die and substrate at a temperature where the epoxy cures for a selected amount of time.

Abstract: In a semiconductor module having the structure in which a bump electrode provided on a wiring layer is connected to a device electrode provided on a semiconductor device, connection reliability between the bump electrode and the device electrode is improved. An insulating resin layer is provided between the semiconductor device and the wiring layer. The bump electrode, formed integrally with the wiring layer and projected from the wiring layer toward the insulating resin layer, is electrically connected to the device electrode provided on the semiconductor device. Part of the height of the wiring layer on the end side in a bump connection area is lower than that of the wiring in a wiring area extending toward the side opposite to the end side.

Abstract: The symbolization of a semiconductor device (100) is incorporated in a thin sheet (130) attached to the top of the device, facing outwardly with its bare surface. The material of the sheet (about 1 to 10 ?m thick) includes regions of a first optical reflectivity and a first color, and regions (133) of a second optical reflectivity and a second color, which differ from, and contrast with, the first reflectivity and color. Preferred choices for the sheet material include the compound o-cresol novolac epoxy and the compound bisphenol-A, more preferably with the chemical imidazole added to the film material. A preferred embodiment of the invention is a packaged device with a semiconductor chip a (101) connected to a substrate (102); the connection is achieved by bonding wires (111) forming an arch with a top 111a. The chip, the wire arches, and the substrate are embedded in an encapsulation material (120), which borders on the attached top sheet so that the arch tops touch the border (131).

Abstract: A manufacturing method of a semiconductor structure includes providing a substrate having an upper surface and a bottom surface. First openings are formed in the substrate. An oxidization process is performed to oxidize the substrate having the first openings therein to form an oxide-containing material layer, and the oxide-containing material layer has second openings therein. A conductive material is filled into the second openings to form conductive plugs. A first device layer is formed a first surface of the oxide-containing material layer, and is partially or fully electrically connected to the conductive plugs. A second device layer is formed on a second surface of the oxide-containing material layer, and is partially or fully electrically connected to the conductive plugs.

Abstract: A redistributed lead frame for use in a molded plastic semiconductor package is formed from an electrically conductive substrate by a sequential metal removal process. The process includes patterning a first side of the substrate to form an array of lands separated by channels; disposing a first molding compound within those channels; patterning a second side of the substrate to form an array of chip attach sites and routing circuits electrically interconnecting the array of lands and the array of chip attach sites; directly electrically interconnecting input/output pads on a semiconductor device to the chip attach sites; and encapsulating the semiconductor device, the array of chip attach sites and the routing circuits with a second molding compound. This process is particularly suited for the manufacture of chip scale packages and very thin packages.

Abstract: A semiconductor package may include a substrate, a semiconductor chip disposed on the substrate, a communication terminal and a static electricity inducing terminal connected to a ground. The package may include a first sealant that comprises a voltage sensitive material and that covers the semiconductor chip and a static electricity blocking layer that provides a conductive pathway from the first sealant to only the static electric inducing terminal. The static electricity blocking layer may prevent the communication terminal from being electrically connected to the first sealant. If a buildup of charge is applied to the device, the first sealant may become polarized and/or conductive. The extra voltage may travel through the first sealant to the static electricity inducing terminal via an opening in the static electricity blocking layer. The semiconductor chip and the communication terminal may not be affected by the extra charge.

Abstract: A ceramic assembly includes one or more electrically and thermally conductive pads to be thermally coupled to a heat generating device, each conductive pad is electrically isolated from each other. The ceramic assembly includes a ceramic layer to provide this electrical isolation. The ceramic layer has high thermal conductivity and high electrical resistivity. A top surface and a bottom surface of the ceramic layer are each bonded to a conductive layer, such as copper, using an intermediate joining material. A brazing process is performed to bond the ceramic layer to the conductive layer via a joining layer. The joining layer is a composite of the joining material, the ceramic layer, and the conductive layer. The top conductive layer and the joining layer are etched to form the electrically isolated conductive pads. The conductive layers are bonded to the ceramic layer using a bare ceramic approach or a metallized ceramic approach.

Abstract: A method for fabricating a chip-scale board-on-chip substrate, or redistribution element, includes forming conductive planes on opposite sides of a substrate. A first of the conductive planes includes two sets of bond fingers, conductive traces that extend from a first set of the bond fingers, and two sets of redistributed bond pads, including a first set to which the conductive traces lead. The second conductive plane includes conductive traces that extend from locations that are opposite from the second set of bond fingers toward locations that are opposite from the locations of the second set of redistributed bond pads. Conductive vias are formed through the second set of bond fingers to the conductive traces of the second conductive plane. In addition, conductive vias are also formed to electrically connect the conductive vias of the second conductive plane to their corresponding redistributed bond pads in the first conductive plane.

Abstract: An integrated circuit package system includes: providing a base package of an elongated rectangular-box shape containing first electrical circuitry and including: forming a rectangular contact strip on and adjacent to a first end of the base package; and forming a base contact pad on and adjacent to a second end of the base package for connection to an electrical interconnect.

Abstract: A semiconductor device including a first memory die having a first memory type, a second memory die having a second memory type different from the first memory type, and a logic die such as a microprocessor. The first memory die can be electrically connected to the logic die using a first type of electrical connection preferred for the first memory type. The second memory die can be electrically connected to the logic die using a second type of electrical connection different from the first type of electrical connection which is preferred for the second memory type. Other devices can include dies all of the same type, or two or more dies of a first type and two or more dies of a second type different from the first type.