Abstract: A universal substrate includes a plurality of inner pads and a plurality of outer pads. A plurality of bifurcate wirings and a plurality of fuses are formed on a surface of the substrate. The fuses are connected with the bifurcate wirings in series. By the bifurcate wirings and the fuses, each of the inner pads is electrically connected to all of the outer pads to provide optional electrical disconnections therebetween. Accordingly, the universal substrate can provide for various chips with different serial arrangements of bonding pads without replacing or manufacturing another kind of substrate.

Abstract: A semiconductor device includes a header, a semiconductor chip fixed to the header constituting a MOSFET, and a sealing body of insulating resin which covers the semiconductor chip, the header and the like, and further includes a drain lead contiguously formed with the header and projects from one side surface of the sealing body, and a source lead and a gate lead which project in parallel from one side surface of the sealing body, and wires which are positioned in the inside of the sealing body and connect electrodes on an upper surface of the semiconductor chip and the source lead and the gate lead, with a gate electrode pad arranged at a position from the gate lead and the source lead farther than a source electrode pad.

Abstract: A method for fabricating a semiconductor component with through interconnects can include the steps of providing a semiconductor substrate with substrate contacts, and forming openings from a backside of the substrate aligned with the substrate contacts. The method can also include the steps of providing an interposer substrate (or alternately a second semiconductor substrate), forming projections on the interposer substrate (or on the second semiconductor substrate), and forming conductive vias in the projections. The method can also include the steps of placing the projections in physical contact with the openings, and placing the conductive vias in electrical contact with the substrate contacts. The method can also include the steps of bonding the conductive vias to the substrate contacts, and forming terminal contacts on the interposer substrate (or alternately on one of the semiconductor substrates) in electrical communication with the conductive vias.

Abstract: A tape wiring substrate may have dispersion wiring patterns. The dispersion wiring patterns may be provided between input/output wiring pattern groups to compensate for the intervals therebetween. Connecting wiring patterns may be configured to connect the dispersion wiring patterns to a first end of the adjacent input/output wiring pattern.

Abstract: A capacitive interposer (caposer) is disposed inside an integrated circuit package between a die and an inside surface of the package. Conductive layers within the caposer constitute a bypass capacitor. In a through-hole caposer, micro-bumps on the die pass through through-holes in the caposer and contact corresponding landing pads on the package. As they pass through the caposer, power and ground micro-bumps make contact with the plates of the bypass capacitor. In a via caposer, power and ground micro-bumps on the die are coupled to power and ground landing pads on the package as well as to the plates of the bypass capacitor by power and ground vias that extend through the caposer. In signal redistribution caposer, conductors within the caposer redistribute signals between die micro-bumps and package landing pads. In an impedance matching caposer, termination structures within the caposer provide impedance matching to a printed circuit board trace.

Abstract: To miniaturize a semiconductor device, a package substrate is provided having terminals formed on the main surface, lands formed on the back surface, through holes formed by laser beam machining and arranged at the upper part of each of the lands, and plating films arranged in the through hole to connect the lands with the terminals electrically. A semiconductor chip is mounted on the main surface of the substrate, a conductive wire connects the pad of the chip and the substrate, and solder bumps are formed in the lands. Since the through holes are formed by laser beam machining, the openings of the through holes are small. Further, the through holes have a larger opening on the main surface of the package substrate than the opening on the back surface of the package substrate. Therefore, it becomes possible to arrange a solder bump directly under each of the through holes, and miniaturization can be realized.

Abstract: In a bonding configuration for a semiconductor device package, the bonding angles of the bonding wires are maintained within acceptable limits, without causing an increase in the chip die size, and without necessitating the use of the corner rule. In this manner, the occurrence of shorting between adjacent bonding wires can be mitigated or eliminated, and device net die count during fabrication can be increased.

Abstract: There is provided a resin-seal type semiconductor device (BGA type semiconductor device) whose heat dissipating characteristic is improved, so that it is prevented from deteriorating in reliability. This BGA type semiconductor device includes a wiring substrate on a predetermined area on which a semiconductor chip is mounted; a plurality of metal bumps that are formed to be arranged at predetermined intervals in an area of the substrate different from the area on which the semiconductor chip is mounted; and a sealing resin layer that covers at least the semiconductor chip. Each of the plurality of metal bumps is covered with the sealing resin layer described above, with a part thereof exposed at a top face of the sealing resin layer.

Abstract: A semiconductor device includes two or more semiconductor devices with bond pads that are electrically connected to the same, single surface of a plurality of leads. The two or more devices may include substantially centrally located bond pads or substantially identically arranged bond pads.

Abstract: A dummy circuit pattern is disclosed on a surface of a substrate for a semiconductor package. The dummy circuit pattern includes a plurality of straight line segments and a plurality of interrupt patterns to breakup one or more of the straight line segments. The interrupt patterns are provided so as to not electrically isolate areas of the dummy pattern, thus providing electrical continuity across the dummy circuit pattern.

Abstract: A package structure for a semiconductor device comprises a substrate having a main surface and a back surface, a semiconductor chip formed on the main surface of the substrate, a package covering the semiconductor chip, radiation protrude electrodes and connection protrude electrodes. The radiation protrude electrodes are formed on the back surface of the substrate in a chip area where said semiconductor chip is located. Each of the radiation protrude electrodes are formed with a first pitch so that the radiation protrude electrodes make one body joining layer when the package structure is subjected to a heat treatment. The connection protrude electrodes are formed on the back surface of the substrate in a peripheral area of the chip area. Each of the connection protrude electrodes formed with a second pitch which is larger than the first pitch so that the connection protrude electrodes stay individual when the package structure is subjected to a heat treatment.

Abstract: The present invention relates to a three-dimensional semiconductor module having at least one unit semiconductor device connected to the outer-facing side surfaces of a multi-side ground block. The unit semiconductor device has a structure in which a semiconductor package (or semiconductor chip) is mounted on a unit wiring substrate. Ground pads to be connected to the outer-facing side surfaces of the ground block are formed on the first surface of the unit wiring substrate, the semiconductor chip is mounted on the second surface opposite to the first surface, and contact terminals electrically connected to the semiconductor chip are formed on the second surface.

Abstract: An integrally packaged integrated circuit device including an integrated circuit die including a crystalline substrate having first and second generally planar surfaces and edge surfaces and semiconductor circuitry formed over the first generally planar surface, at least one chip scale packaging layer formed over the semiconductor circuitry and the first generally planar surface, an insulation layer formed over the second generally planar surface and the edge surfaces and at least one electrical conductor formed directly on the insulation layer overlying the second generally planar surface, the at least one electrical conductor being connected to the circuitry by at least one pad formed directly on the first generally planar surface.

Abstract: Methods for forming flip chip interconnection, in which the bump interconnect is defined at least in part by an underfill. The underfill includes a material that is thermally cured; that is, raising the temperature of the underfill material can result in progressive curing of the underfill through stages including a gel stage and a fully cured stage. According to the invention, during at least an early stage in the process the semiconductor chip is carried by a thermode, which is employed to control the temperature of the assembly in a specified way. Also, flip chip interconnections and flip chip packages made according to the methods of invention.

Abstract: A chip-on-film package may include a tape wiring substrate, a semiconductor chip mounted on the tape wiring substrate, and a molding compound provided between the semiconductor chip and the tape wiring substrate. The tape wiring substrate may include a film having upper and lower surfaces. Vias may penetrate the film. An upper metal layer may be provided on the upper surface of the film and include input terminal patterns and/or output terminal patterns. The input terminal patterns may include ground terminal patterns and/or power terminal patterns. A lower metal layer may be provided on the lower surface of the film and include a ground layer and/or a power layer. The ground layer and the power layer may cover at least a chip mounting area.

Abstract: A universal substrate and a semiconductor device utilizing the substrate are disclosed in the present invention. The universal substrate mainly comprises a plurality of inner pads and a plurality of outer pads. A plurality of bifurcate wirings and a plurality of fuses are formed on a surface of the substrate. The fuses are connected with the bifurcate wirings in series. By the bifurcate wirings and the fuses, each of the inner pads is electrically connected to all of the outer pads to provide optional electrical disconnections therebetween. Accordingly, the universal substrate can be utilized for connecting chips having various serial arrangements of bonding pads without replacing or manufacturing another substrate.

Abstract: An integrated circuit comprises a package and having adjacent connection pins on two opposite sides of the package, with every second connection pin being inwardly bent so that the connection pins are offset. The ends of the inwardly bent connection pins and the ends of the outer connection pins each lie on a straight line, where the offset connection pins are bent by different angles out of the plane of the package.

Abstract: A stacked structure of semiconductor chips includes plural stacked semiconductor chips and plural tabular holding members which hold the respective semiconductor chips.

Abstract: An integrated circuit module has a common function known good integrated circuit die with selectable functions. The selectable functions are selected during packaging of the known good integrated circuit die. The known good integrated circuit die is mounted to a second level substrate. The second level substrate has wiring connections to the input/output pads of the known good integrated circuit die that select desired input functions and output functions. Further, the wiring connections on the second level substrate provide signal paths to transfer signals to the desired input function and signals from the desired output function, and signals to and from the common functions. Also, the wiring connections form connections between the input/output pads and external circuitry. To select the desired input functions and the desired output functions, appropriate logic states are applied to input/output pads connected to a function selector to configure a functional operation of the integrated circuit module.

Abstract: A semiconductor device includes a first wiring layer having a first wiring pitch and a second wiring layer having a second wiring pitch that differs from the first wiring pitch. The device further includes a third wiring layer which connects the first wiring layer and the second wiring layer and has a wiring incident angle of less than 45 degrees to at least the first wiring layer.

Abstract: Methods of forming a microelectronic device and associated structures are described. Those methods may comprise forming a die-side conductive interconnect on a substrate, wherein the die-side conductive interconnect comprises a columnar portion and a base portion, and wherein a diameter of the base portion is greater than a diameter of the columnar portion.

Abstract: The present invention provide a wafer level chip size packaged chip device with a N-shape junction at which external leads electrically connect to peripheral arrayed compatible pads and a method of fabricating the same. In the wafer level chip size package, with such an n-shape junction instead of a conventional T-shape junction observed in Shellcase type wafer level chip size package technology, electrical connections between compatible pads and external leads are more reliable due to larger connection area than the counterpart in the T-shape junction.

Abstract: An electronic device. The device comprises a metalization layer and an integrated circuit chip incorporated into the device wherein the integrated circuit chip is capacitively coupled to the metalization layer. The device comprises a first substrate having the metalization layer formed on the substrate, a cap layer covering at least the entire metalization layer and at least a portion of the first substrate not covered by the metalization layer. The integrated circuit chip is coupled to the first substrate, and is placed in proximity and in non-physical contact with the metalization layer. A conductive layer is attached to the integrated circuit chip. The conductive layer has at least a portion placed in a non-physical contact with the metalization layer. The integrated circuit chip is capacitively coupled to the metalization layer through the conductive layer and the metalization layer.

Abstract: A semiconductor device includes a tape carrier substrate having a flexible insulating film base, a plurality of conductor wirings provided on the film base, and wiring bumps respectively formed so as to cover an upper surface and both side surfaces of the conductor wirings, and a semiconductor chip mounted on the tape carrier substrate, wherein electrodes of the semiconductor chip are connected to the conductor wirings via the wiring bumps. Electrode bumps are formed on the electrodes of the semiconductor chip, the electrodes of the semiconductor chip are connected to the conductor wirings via a bonding between the wiring bumps and the electrode bumps, and the electrode bumps are harder than the wiring bumps. This structure can reduce bonding damages to the electrodes of the semiconductor chip caused by a process of connecting the electrodes and the conductor wirings via the bumps.

Abstract: Thinning and stacking are essential for circuit modules used for mobile devices of various kinds, smart cards, memory cards and the like. These demands make the manufacture of the circuit modules more complicated or less reliable due to delamination. A circuit module of a multilayer structure is provided which is formed by embedding semiconductor chips and passive components in a sheet made from a thermoplastic resin; folding a module sheet, which is formed of circuit blocks provided with wiring patterns thereon, at the boundaries of the circuit blocks so as to be stacked into layers; and thermal-bonding and integrating the module sheet by applying heat and pressure. As a result, a highly reliable circuit module can be manufactured in a simple manner.

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: An electronic circuit device has a high-density mount board (2), on which are disposed a microcomputer (3) and random access memory (7) which are connected to each other through an exclusive memory bus (12) for high-speed data transfer, a programmable device (8) which is a variable logic circuit represented by FPGA, and an electrically-rewritable nonvolatile memory (16) which can store the operation program of the microcomputer. The high-density mount board has external mounting pins on the bottom surface so that it can be mounted on a mother board in the same manner as a system on-chip multi-chip module. With an intended logic function being set on the programmable device, a hardware-based function to be realized by the electronic circuit device can be simulated. With an operation program being written to the nonvolatile memory, a software-based function to be realized can be simulated.

Abstract: A wiring board comprising: a plate core having a first main surface and a second main surface; conductor layers including a conductor line; dielectric layers laminated alternately with said conductor layers on at least one of said first and second main surfaces; via conductors as defined herein; a signal through-hole as defined herein; a signal through-hole conductor as defined herein; a first path end pad as defined herein; a second path end pad as defined herein; a shield through-hole as defined herein; and a shield through-hole conductor as defined herein; wherein: a signal transmission path is formed as defined herein; at least one of said conductor layers is disposed on each of said first and second main surface sides; said surface conductor on said first main surface side and said conductor line form a strip line, a microstrip line, or a coplanar waveguide with constant characteristic impedance Z0; an inner surface of said shield through-hole is covered with said shield through-hole conductor; and an in

Abstract: An electronic package which includes a circuitized substrate having at least two electrical components positioned thereon. The package includes patterns of contact sites, each for having one of the components coupled thereto. The patterns of contact sites in turn are electrically interconnected by a grouping of conductive lines which, to substantially prevent skew, are of substantially the same length. A method of making the package is also provided, as is a circuitized substrate and an information handling system, the latter adapted for having one or more of the electronic packages as part thereof.

Abstract: A pattern of contacts that includes high speed transmitter contacts disposed in a first portion of the pattern, where the high speed transmitter contacts are disposed in transmitter differential pairs. High speed receiver contacts are disposed in a second portion of the pattern, where the first portion of the pattern is not interspersed with the second portion of the pattern, and the high speed receiver contacts are disposed in receiver differential pairs. At least one unbroken line of other contacts is disposed between the first portion of the pattern and the second portion of the pattern, where the other contacts do not contain any high speed transmitter contacts and high speed receiver contacts. Low speed IO contacts are disposed in a third portion of the pattern, where the third portion of the pattern is disposed in an interior portion of the pattern relative to both the first portion of the pattern and the second portion of the pattern.

Abstract: Wire bonding methods and apparatuses are described herein. In one aspect of the invention, an exemplary apparatus includes a plurality of electrically conductive contacts disposed on a surface of the IC device, the plurality of electrically conductive contacts being disposed in at least two rows, a plurality of first return paths formed through some of the plurality of electrically conductive contacts, a plurality of signal paths formed through some of the plurality of electrically conductive contacts, and wherein at least one of the plurality of first return paths are placed between every predetermined number of the plurality of the signal-paths. Other methods and apparatuses are also described.

Abstract: A family of package substrates adapted to receive a family of integrated circuits having different sizes and provide electrical connections between the integrated circuits and a circuit board. Each package substrate in the family includes a package substrate having a die side and a circuit board side. The package substrate has a size that is consistent for all of the package substrates in the family of package substrates. The die side has integrated circuit contacts disposed in a pattern designed to make electrical connections to a given integrated circuit in the family of integrated circuits for which the package substrate is designed, as defined by locations of contacts on the given integrated circuit. The circuit board side has circuit board contacts disposed in a pattern and with functional assignments that are consistent for all of the package substrates in the family of package substrates.

Abstract: A substrate (1) is formed from a non-electrically conducting material and is for mounting a semiconductor chip (10). The substrate has a semiconductor chip mounting portion (6). A number of first electrically conducting contact portions (5) are formed on the surface of the material and associated with the mounting portion (6). A second electrically conducting contact portion (3) is formed on the surface of the material, and the second electrically conducting contact portion (3) is adapted to be coupled to testing equipment. A number of electrically conducting paths (4) are formed on the surface of the material. The conducting paths (4) electrically connect the second electrically conducting contact portion (3) to a minority of the first electrically conducting contact portions (5).

Abstract: A chip-mounted film package includes a base film, an effective film package defined on the base film by a cutting line, a driving chip mounted on the effective film package, a plurality of input pads arranged on an input area of the effective film package and connected to the driving chip, and a plurality of output pads arranged on an output area of the effective film package and connected to the driving chip, wherein the output area includes at least one extended portion that protrudes from a side of the effective film package in a horizontal direction of the base film.

Abstract: A support structure for a semiconductor device with peripherally disposed contacts includes a support substrate and at least one conductive column protruding from the support substrate. The at least one conductive column is configured to contact an outer connector on a peripheral edge of a semiconductor device that may be carried by the support structure. Optionally, the at least one conductive column may engage a feature of (e.g., a recess in) the peripherally disposed outer connector. The at least one conductive column may facilitate alignment of one or more semiconductor devices with the support substrate alignment of semiconductor devices relative to one another, or electrical connection between multiple semiconductor devices of other components.

Abstract: A rerouting element for a semiconductor device includes a dielectric film that carries conductive vias, conductive elements, and contact pads. The conductive vias are positioned at locations that correspond to the locations of bond pads of a semiconductor device with which the rerouting element is to be used. The conductive elements, which communicate with corresponding conductive vias, reroute the bond pad locations to corresponding contact pad locations adjacent to one peripheral edge or two adjacent peripheral edges of the rerouted semiconductor device. The rerouting element is particularly useful for rerouting centrally located bond pads of a semiconductor device, as well as for rerouting the peripheral locations of bond pads of a semiconductor device to one or two adjacent peripheral edges thereof. In addition, methods for designing and using rerouting elements are disclosed.

Abstract: A semiconductor die includes a plurality of drivers and a plurality of bonding pads. Each driver is formed by a plurality of interconnected modules and has an associated bonding pad to which at least one of the modules of the driver is electrically connected. The modules of some of the drivers are positioned outside of the associated bonding pad toward a periphery of the die. The bonding pads may be arranged, for example, in a double- or triple-staggered pattern around the periphery of the die.

Abstract: A method for manufacturing a semiconductor device is provided. A resin paste is applied to a wiring base including a wiring pattern. Then, a semiconductor chip having a plurality of electrodes is mounted to the wiring base. The electrodes and the wiring pattern face one another and are electrically connected. The wiring base and the semiconductor chip are bonded by curing the resin paste. The wiring pattern includes a wiring that continuously includes two or more first parts located inside a semiconductor chip mounting region and a second part that connects at least two of the first parts. The second part is located outside the semiconductor chip mounting region.

Abstract: A semiconductor package is disclosed with a recess (51) for an integrated circuit die (52). The recess is made by bending or deforming all layers of a package substrate, and therefore the recess contains circuitry to connect to the integrated circuit die. The integrated circuit die is electrically connected to the package substrate by either wirebonds (53a), TAB or die solder balls (53b). The package substrate (50), a single sided printed wiring board, has a thick metal core (100) and one or more thin build up layers.

Abstract: A semiconductor device including: a semiconductor substrate in which an integrated circuit is formed; an insulating layer formed on the semiconductor substrate and having a first surface and a second surface which is higher than the first surface; a first electrode formed to avoid the second surface and electrically connected to the inside of the semiconductor substrate; and a second electrode formed on the second surface and electrically connected to the inside of the semiconductor substrate.

Abstract: A package for a semiconductor die comprises a semiconductor die with a bond pad. The package further includes a package lead and a bond wire with a first end portion coupled to the package lead, a second end portion coupled to the bond pad, and an intermediate portion. A non-conductive intermediate lead finger mounting substrate with an intermediate lead finger is positioned within the package. The intermediate lead finger is positioned between the lead finger and the bond pad and is attached to the intermediate portion of the bond wire.

Abstract: An example of a semiconductor device of the present invention includes a first semiconductor element including a first element body portion and a first element electrode that is provided on a first face of the first element body portion; a wiring board including an insulating substrate and a first wiring layer that is formed on one principal face of the insulating substrate, the wiring board being disposed such that the one principal face of the wiring board is opposed to a second face of the first element body portion; a first film that covers at least a portion of a face of the first semiconductor element that includes the surface of the first element electrode and at least a portion of a face on the first semiconductor element side of the wiring board; and a second wiring layer that is formed on a face on the wiring board side of the first film and that includes a first conductor having first and second ends.

Abstract: First bump electrodes are arrayed in a straight line along a first side of a semiconductor chip. Second bump electrodes are more narrowly arrayed in a zigzag arrangement along a second side of the chip. By carrying out an injection of a sealing resin from the second side on which the second bump electrodes are arrayed, a surface of the semiconductor chip that is subjected to face-down mounting on a film substrate is sealed.

Abstract: A process and electronic assembly for conducting heat from a semiconductor circuit device mounted to a substrate. The substrate is supported by a housing member equipped with a heat-conductive member. A surface of the device opposite the substrate is bonded to the heat-conductive member with a solder joint formed of indium and optionally one or more alloying constituents that increase the melting temperature of the solder joint above that of indium. The housing member, substrate, and device are assembled so that an indium-containing solder material is present between the heat-conductive member and the surface of the device opposite the substrate. The solder material is then reflowed to form the solder joint. The alloying constituent(s) are preferably introduced into the solder joint during reflow.

Abstract: A die-wafer package includes a singulated semiconductor die having a first plurality of bond pads on a first surface and a second plurality of bond pads on a second opposing surface thereof. Each of the first and second pluralities of bond pads includes an under-bump metallization (UBM) layer. The singulated semiconductor die is disposed on a semiconductor die site of a semiconductor wafer and a first plurality of conductive bumps electrically couples the first plurality of bond pads of the singulated semiconductor die with a first set of bond pads formed on the semiconductor die site. A second plurality of conductive bumps is disposed on a second set of bond pads of the semiconductor die site. A third plurality of conductive bumps is disposed on the singulated semiconductor die's second plurality of bond pads. The second and third pluralities of conductive bumps are configured for electrical interconnection with an external device.

Abstract: A method for directly aligning multiple lithography masking layers. The method may be used to fabricate a flash plus logic structure. The flash plus logic structure may comprise a flash memory cell, a logic cell and a transistor.

Abstract: The present invention provides a system for implementing a configurable integrated circuit (IC). Aspects of the invention include an IC die; a plurality of input/outputs (I/Os) coupled to the IC die; and a plurality power planes coupled to the IC die for providing power to the plurality of I/Os at different voltages. The plurality of power planes are configured concentrically around the IC die so that any one or more of the I/Os at any location on the IC die can be individually configured to connect to any of the power planes. As a result, any number of I/Os available on the IC die can operate at a given voltage.

Abstract: A circuit arrangement permits a microcontroller wirebond pad to be configured to be an analog or digital input or output. The circuit arrangement uses any of a plurality of switching configurations to selectively determine the use of the wirebond pad under control of the microcontroller's processor. The microcontroller can be configured using configurable analog and configurable digital blocks to perform any of a plurality of functions with certain of the pinouts determined under program control.

Abstract: An electrical device includes electrical contact pads, a supply voltage bus and an interconnection circuit. The electrical contact pads receive a supply voltage, and the bus is electrically connected to the electrical contact pads. For each electrical contact pad, the interconnection circuit forms a redundant connection between the bus and the electrical contact pad. The electrical device may include a passivation layer that includes windows to establish electrical contact between the electrical contact pads and the supply voltage bus. This window may be elongated in a path that is generally aligned with the path along which the supply voltage bus extends.

Abstract: The escape of signals from a semiconductor chip to a printed wiring board in a flip chip/ball grid array assembly is improved by repositioning the signals from the chip through the upper signal layers of the carrier. This involves fanning out the circuit lines through the chip carrier from the top surface that communicates with the chip, through the core to the bottom surface where signals exit the carrier to the printed wiring board. This fanning out is achieved by making better utilization of the surface area of the signal planes between the core and the chip. The signals are fanned out on each of the top signal planes so that many more of the signals are transmitted through the vias in the core to the bottom signal planes where they can escape outside of the footprint area of the chip thereby increasing the density of circuits escaping the footprint area.