Abstract: Disclosed herein is a lead pin for a package substrate including a connection pin, and a head part including a flange part formed at one end of the connection pin and having one surface bonded to the connection pin and a flat part formed at the other surface of the flange part and having at least one groove formed along an outer circumference thereof. According to the present invention, the grooves are formed along the outer circumference of the flat part of the head part of the lead pin to increase a bonding area, thereby making it possible to increase bonding strength of the lead pin.

Abstract: Disclosed is a liquid crystal driver having a plurality of output cells (101), wherein operational amplifiers (105), which are components of the output cells (101), are connected to a power wire (109a) formed in the liquid crystal driver, which is a semiconductor element. Further, the semiconductor element is mounted on a substrate on which a bypass wire (201) has been formed. The bypass wire (201) is connected to the power wire (109a) through bumps (203) for each separate one of the operational amplifiers (105) of all of the output cells.

Abstract: Consistent with an example embodiment, there is an integrated circuit (IC) device in a packaging having electrically insulated connections. The IC device comprises a semiconductor device (100) mounted onto a die attachment area (10); the semiconductor device has a plurality of bonding pads (20a, 25a, 30a, 35a). A lead frame having a plurality of bonding fingers (20b, 25b, 30b, 35b) surrounds the die attachment area. A plurality of mutually isolated connection conductors (25d, 30d, 40, 50) having respective first ends are attached to respective bonding pads on the semiconductor device and the plurality of mutually isolated connection conductors having respective second respective second ends are attached to respective bonding fingers of the lead frame. An insulating material (45) coats at least a portion of the plurality of mutually isolated connection conductors.

Abstract: The present invention provides a non-insulated type DC-DC converter having a circuit in which a power MOS•FET for a high side switch and a power MOS•FET for a low side switch are connected in series. In the non-insulated type DC-DC converter, the power transistor for the high side switch, the power transistor for the low side switch, and driver circuits that drive these are respectively constituted by different semiconductor chips. The three semiconductor chips are accommodated in one package, and the semiconductor chip including the power transistor for the high side switch, and the semiconductor chip including the driver circuits are disposed so as to approach each other.

Abstract: Disclosed is a semiconductor device having a multilayer wiring structure, in which a dummy pattern is formed in a wiring void with favorable manufacturing efficiency. In a semiconductor device having a multilayer wiring structure, dummy pattern (21) is formed in relatively narrow wiring void (Area_S1) so as to extend in a direction different from that of dummy patterns (22, 23) formed in relatively wide wiring void (Area_S2).

Abstract: A semiconductor product is constructed of a wiring substrate in which pads for pin connection are formed, and a substrate with pins in which pins are disposed. The substrate with the pins is formed so that one end of the pin is exposed to one surface of a resin substrate formed by resin molding and the other end of the pin extends from the other surface of the resin substrate and one end of the pin is bonded to a pad of the wiring substrate through a conductive material.

Abstract: A silicon structure includes a silicon substrate having an electric element; a wiring conductor and a bonding pad, connecting the electric element and an external circuit; a protective layer disposed on the silicon substrate; and a pad opening pattern provided in the protective layer to exposed the bonding pad, wherein a probe mark position and a wire bonding position differ, without increasing the size of the bonding pad in plan view. A substrate exposure part, which is not covered with the protective layer, is provided at part of an outer edge of the bonding pad disposed inside the pad opening pattern in the protective film, and the wiring conductor is not exposed through substrate exposure part.

Abstract: A semiconductor device includes a base substrate including an internal circuit, a resin protrusion part that is disposed to protrude on an active face side of the base substrate, and a plurality of terminals that are formed by including an island-shaped conductive film disposed on the resin protrusion part. The plurality of terminals includes a terminal that a conductive state with the internal circuit, and a wiring line that electrically connects at least two terminals among the plurality of terminals is disposed on the active face side.

Abstract: A semiconductor device includes at least bonding wires between electrode pads on a main surface of a semiconductor chip and connection pads on a wiring board. The wires form loop shapes from the electrode pads of the semiconductor chip. The semiconductor device also includes at least forming flat parts on the loop-shaped wires, and using a sealing material to seal the semiconductor chip such as to bury the flat parts.

Abstract: A semiconductor chip pad structure and a method for manufacturing the same, wherein a flat area at the center of the terminal pad and a roughened area at the periphery thereof are provided by use of the mask photolithograph technique and the roughening process. The central area provides a sufficient adhering force for the ball bond while the peripheral area prevents the wire-bonding vibrating energy from the lateral transmission to the external side of the terminal pad. In this way, the ball bond for the terminal pad may meet the wire-bonding requirements. Moreover, the ball bond quality is ensured.

Abstract: Disclosed herein is a lead pin for a package substrate. The lead pin for the package substrate according to the exemplary embodiment of the present invention includes a head part having one surface opposite to the package substrate and the other surface that is an opposite side to the one surface; and a connection pin having a pin shape bonded to the other surface of the head part, wherein the head part has a concave depression part toward the package substrate.

Abstract: A semiconductor package includes a first package including a first substrate and at least one first semiconductor chip mounted on the first substrate, a redistribution wiring layer provided on the first package and including a connection pad, a bonding pad electrically connected to the connection pad and a dummy bonding pad electrically connected to the bonding pad, a second package stacked on the first package via the redistribution wiring layer and electrically connected to the connection pad of the redistribution wiring layer by a first connection member, a bonding wire electrically connecting the bonding pad to the first substrate, and a dummy bonding wire electrically connecting the dummy bonding pad to the first substrate.

Abstract: An integrated circuit package system includes: providing a substrate; attaching a base die to the substrate, the base die having a relief region with a shaped cross-section; and connecting a bond wire between an active base surface of the base die and the substrate, the bond wire extending through the shaped cross-section of the relief region.

Abstract: A microelectronic assembly includes an interconnection element, element contacts, first and second metal layers, conductive elements, and first and second microelectronic devices. The first metal layer may extend beyond at least one of the edges of the first microelectronic device. The conductive elements may respectively extend beyond at least one of the edges of the first metal layer. The first metal layer may have a surface disposed at a substantially uniform spacing from at least substantial portions of the conductive elements, such that a desired impedance may be achieved for the conductive elements. The conductive elements may be spaced a smaller distance from the metal layer than the distance of the conductive elements from the front surface of the first microelectronic device. The second metal layer may be connectable to a source of reference potential.

Abstract: An integrated circuit package system includes: connecting a carrier and an integrated circuit mounted thereover; preforming a wire-in-film encapsulation having a cavity; pressing the wire-in-film encapsulation over the carrier and the integrated circuit with the cavity exposing a portion of the integrated circuit; and curing the wire-in-film encapsulation.

Abstract: A die structure includes a die and a metallization layer disposed over the front side of the die. The metallization layer includes copper. At least a part of the metallization layer has a rough surface profile. The part with the rough surface profile includes a wire bonding region, to which a wire bonding structure is to be bonded.

Abstract: A semiconductor device comprises a semiconductor element having electrodes, a metal member, wires that electrically connect the semiconductor element and the metal member and/or electrodes within the semiconductor element, wherein the wires constitute at least a first wire loop and a second wire loop, the first wire loop is bonded at one end to a first bonding point and at the other end to a second bonding point, and has a flat part which includes the surface of a boll part and the wire located contiguously the ball part surface, and the second wire loop connects the surface of the ball part and a third bonding point.

Abstract: To provide a small, high-performance semiconductor device in which contact between adjacent wires is prevented for increased flexibility in designing a wiring layout, and an efficient method for manufacturing the semiconductor device. The semiconductor device includes a substrate 10 having an electrode 21A arranged on its surface; and a first semiconductor element 11A which includes an electrode 22 arranged on its surface and which is supported by the substrate 10, wherein a first wire 41 is connected through a first bump 31 to at least one of the electrodes over the substrate 10 and semiconductor element 11A (i.e., at least one of the electrodes 21 and 22), and a second wire 42 is connected through a second bump 32 to a bonding portion of the wire 41.

Abstract: A method of manufacture of a semiconductor package includes: providing a substrate; mounting a semiconductor die on the substrate, the semiconductor die having a die pad; mounting a lead finger on the substrate; attaching a support pedestal on sides of the lead finger; and attaching a wire interconnection between the die pad and the support pedestal, the wire interconnection having a ball bond on the die pad and a stitch bond on the support pedestal.

Abstract: A plurality of FPGA dice is disposed upon a semiconductor substrate. In order to supply the immense power required by the plurality of FPGA dice, power is routed through the semiconductor substrate vertically from thick metal layers and large integral metal structures located on the other side of the semiconductor substrate. Because the semiconductor substrate has a different coefficient of thermal linear expansion than metal layers in contact with the substrate, delamination may occur when the structure is subject to changes in temperature. To prevent delamination of metal layers connected to the semiconductor substrate and in electrical contact with the integral metal structures, the integral metal structures are manufactured with an array of post portions. During changes in temperature, the post portions of the integral metal structures bend and slide relative to metal layers connected to the semiconductor substrate and prevent linear stresses that may otherwise cause delamination.

Abstract: A method for die stacking is disclosed. In one embodiment a first die is formed overlying a substrate. A first wire is bonded to the first die and to a bond finger of the substrate, wherein the first wire is bonded to the bond finger with a first bond. A first stitch bump is formed overlying the first stitch bond, wherein the first stitch bump is formed from a molten ball of conductive material. A second die is formed overlying the first die. A second wire is bonded to the second die and to the first stitch bump, wherein the second wire is bonded to the first stitch bump with a second bond.

Abstract: A method of manufacturing semiconductor device includes preparing a substrate having a first surface and a second surface opposite to the first surface. A first insulation layer is formed on the second surface. A sacrificial layer is formed on the first insulation layer. An opening is formed to penetrate through the substrate and extend from the first surface to a portion of the sacrificial layer. A second insulation layer is formed on an inner wall of the opening. A plug is formed to fill the opening. The sacrificial layer is removed to expose a lower portion of the plug through the second surface.

Abstract: A semiconductor package and a method of manufacturing the package are provided. The semiconductor package comprises: a mounting substrate including a bond finger; at least one semiconductor chip disposed on the mounting substrate, the semiconductor chip including a bonding pad; a first molding member disposed on the mounting substrate so as to cover the bond finger and the bonding pad, the first molding member including an interconnection path disposed inside the first molding member so as to connect the bond finger to the bonding pad; a conductive element disposed in the interconnection path; and a second molding member overlying the first molding member. The interconnection path can be formed by a laser process. The conductive element can be formed by conductive nanoparticles or metal wires.

Abstract: Methods and systems are described for enabling the efficient fabrication of wedge bonding of integrated circuit systems and electronic systems. In particular a reverse bonding approach can be employed.

Abstract: An integrated circuit assembly is fabricated on a metal substrate strip in an array format that has raised circuitry pattern formed by photolithographic and metal etching processes. The circuitry pattern is formed on one side of the metal substrate only. The raised circuitry's etch depth extends partially through the metal substrate. Die attachment can be performed using a non-conductive material applied directly onto and around the raised circuitry features directly under the die. After wirebond and molding processes, the molded metal substrate strip assembly is processed through a metal etching process to remove the metal substrate portion that is exposed beyond the mold cap. A solder mask coating can be applied to protect the metal circuitry and to define the package pad opening to form Land-Grid-Array (LGA) packages. Solder balls can also be attached to form Ball-Grid-Array (BGA) packages.

Abstract: The semiconductor device according to the present invention includes a semiconductor chip, an island having an upper surface to which the semiconductor chip is bonded, a lead arranged around the island, a bonding wire extended between the surface of the semiconductor chip and the upper surface of the lead, and a resin package collectively sealing the semiconductor chip, the island, the lead and the bonding wire, while the lower surface of the island and the lower surface of the lead are exposed on the rear surface of the resin package, and the lead is provided with a recess concaved from the lower surface side and opened on a side surface thereof.

Abstract: There is provided a bonding wire which does not cause a leaning failure or the like. A semiconductor mounting bonding wire has a breaking elongation of 7 to 20%, and stress at 1% elongation is greater than or equal to 90% of a tensile strength and is less than or equal to 100% thereof.

Abstract: Embodiments of the present invention relate to an improved die layout for a bi-directional and reverse blocking battery switch. According to one embodiment, two switches are oriented side-by-side, rather than end-to-end, in a die package. This configuration reduces the total switch resistance for a given die area, often reducing the resistance enough to avoid the use of backmetal in order to meet resistance specifications. Elimination of backmetal reduces the overall cost of the die package and removes the potential failure modes associated with the manufacture of backmetal. Embodiments of the present invention may also allow for more pin connections and an increased pin pitch. This results in redundant connections for higher current connections, thereby reducing electrical and thermal resistance and minimizing the costs of manufacture or implementation of the die package.

Abstract: An electrically conductive interconnect system has a post, extending above a supporting surface, the post including a rigid material, a coating on the rigid material, wherein the post and has a first width at the supporting surface and a second width at a distance removed from the supporting surface, and the post narrows from the first width to the second width. A method of electrically connecting a portion of a first supporting surface to a portion of a second supporting surface involves bringing a post on the first supporting surface into contact with an electrically conductive material located on the second supporting surface, softening the electrically conductive material, causing a separation distance between the first supporting surface and the second supporting distance to decrease so that a portion of the post will be surrounded by the electrically conductive material, and allowing the temperature of the electrically conductive material to decrease.

Abstract: According to one embodiment, a semiconductor device includes a first semiconductor element, a first electrode, a ball part, a second electrode, and a wire. The first electrode is electrically connected to the first semiconductor element. The ball part is provided on the first electrode. The wire connects the ball part and the second electrode. A thickness of a turned-back portion at an end of the wire on a side opposite to the second electrode is smaller than a diameter of the wire.

Abstract: A pad structure and passivation scheme which reduces or eliminates IMC cracking in post wire bonded dies during Cu/Low-k BEOL processing. A thick 120 nm barrier layer can be provided between a 1.2 ?m aluminum layer and copper. Another possibility is to effectively split up the barrier layer, where the aluminum layer is disposed between the two barrier layers. The barrier layers may be 60 nm while the aluminum layer which is disposed between the barrier layers may be 0.6 ?m. Another possibility is provide an extra 0.6 ?m aluminum layer on the top barrier layer. Still another possibility is to provide an extra barrier layer on the top-most aluminum layer, such that a top barrier layer of 60 nm is provided on a 0.6 ?m aluminum layer, followed by another harrier layer of 60 nm, another aluminum layer of 0.6 ?m and another barrier layer of 60 nm.

Abstract: A power semiconductor device according to the present invention includes a heat sink made of Cu and having a thickness of 2 to 3 mm, an insulating substrate bonded on the heat sink with interposition of a first bonding layer (under-substrate solder), and a power semiconductor element mounted on the insulating substrate. In the heat sink, a buffer slot is formed at a periphery of a region bonded to the insulating substrate.

Abstract: An integrated circuit package-in-package system including: providing a substrate; mounting a structure over the substrate; supporting an inner stacking module cantilevered over the substrate by an electrical interconnect connected to the substrate, the electrical interconnect forming a gap between the inner stacking module and the structure controlled by the size of the electrical interconnect; and encapsulating the structure and inner stacking module with an encapsulation.

Abstract: A microelectronic assembly includes a semiconductor chip having chip contacts exposed at a first face and a substrate juxtaposed with a face of the chip. A conductive bond element can electrically connect a first chip contact with a first substrate contact of the substrate, and a second conductive bond element can electrically connect the first chip contact with a second substrate contact. The first bond element can have a first end metallurgically joined to the first chip contact and a second end metallurgically joined to the first substrate contact. A first end of the second bond element can be metallurgically joined to the first bond element. The second bond element may or may not touch the first chip contact or the substrate contact. A third bond element can be joined to ends of first and second bond elements which are joined to substrate contacts or to chip contacts.

Abstract: A circuitry comprises a substrate with a terminal region, a semiconductor device with a contact terminal, a bond wire connecting the terminal region to the contact terminal and a solder glass encapsulating material. The solder glass encapsulating material is mounted on the semiconductor device with the bond wire, so that at least the bond wire is hermetically enclosed. The substrate has a substrate material with a first coefficient of thermal expansion, the semiconductor device has a device material with a second coefficient of thermal expansion and the bond wire has a bond wire material with a third coefficient of thermal expansion. The solder glass encapsulating material has a coefficient of thermal expansion adjusted to a predefined value with regard to the second and third coefficients of thermal expansion.

Abstract: A DC voltage conversion module includes a substrate, an input terminal, an output terminal, a ground terminal, a DC voltage conversion control element mounted on the substrate, a coil mounted on the substrate and connected to the DC voltage conversion control element and the output terminal, an input-side capacitor mounted on the substrate and connected to the input terminal and the ground terminal, and an output-side capacitor mounted on the substrate and connected to the output terminal and the ground terminal. The input terminal, the output terminal and the ground terminal project in a predetermined projecting direction parallel to each other. The ground terminal is arranged between the input terminal and the output terminal in a direction perpendicular to the projecting direction.

Abstract: A power switch component having a semiconductor switch and a contacting applied to a contact zone of the semiconductor switch is introduced. The contact zone has a semiconductor layer and a metal plating applied to the semiconductor layer. The semiconductor layer has at least one conducting region and at least one non-conducting region situated directly under the metal plating.

Abstract: A method for manufacturing an integrated circuit package system includes: providing a carrier; mounting an integrated circuit die on a top side of the carrier; connecting the integrated circuit die with the carrier; forming an encapsulation having a multi-sloped side over the integrated circuit die for reducing ejection stress; and forming a first external interconnect on the top side of the carrier adjacent to and separated from the encapsulation including forming a second external interconnect on a bottom side of the carrier opposite the first external interconnect.

Abstract: A wiring substrate includes a silicon substrate, a through hole formed to penetrate the silicon substrate in a thickness direction, an insulating layer formed on both surfaces and side surfaces of the silicon substrate and an inner surface of the through hole, a penetration electrode formed in the through hole, a wiring layer formed on at least one surface of the silicon substrate and connected to the penetration electrode, and a metal wire terminal connected to the wiring layer and formed to extend from one surface of the silicon substrate to a side surface thereof. The metal wire terminal on the side surface of the electronic device is connected to the mounting substrate such that a substrate direction of the electronic device in which an electronic component is mounted on the wiring substrate intersects orthogonally with a substrate direction of the mounting substrate.

Abstract: An electronic component assembly that has a supporting structure, an integrated circuit die with a plurality of contacts pads, a printed circuit board with a plurality of conductors, the integrated circuit die and the PCB being mounted to the supporting structure by a die attach film such that they are adjacent and spaced from each other and, wire bonds electrically connecting the contact pads to the conductors. An intermediate portion of each of the wire bonds is adhered to the die attach film to lower the profile of the wire bond arcs.

Abstract: A packaging technology for silicon chips is similar to ball grid array packaging technology of the prior art without, however, the use of printed board substrate of the prior art Instead pins are used that are part of a planar frame, the pins folded to a position 90 degrees from the plane of the frame, after which the frame is disposed in contact with the chip, pads on the frame and the chip are connected, and then entire assembly is then encapsulated. The edges of the frame are then cut off, leaving the encapsulation to maintain the configuration of the package in place.

Abstract: A semiconductor device is provided by the present invention. The semiconductor device includes a first semiconductor die comprising at least a first bond pad; and a second semiconductor die comprising at least a second bond pad with voltage level equivalent to the first bond pad of the first semiconductor die; wherein the first bond pad of the first semiconductor die is electrically connected to the second bond pad of the second semiconductor die via at least a bond wire. The semiconductor device of the present invention is capable of solving the IR drop of the semiconductor die with low cost.

Abstract: A heterogeneous integrated circuit having at least one tier made of multiple technologies and a method of making the heterogeneous integrated circuit. The heterogeneous integrated circuit includes a package substrate, a first die of a first technology, and a second die of a second technology, where the two dies are located in the same tier. One die can surround the other die. The heterogeneous integrated circuit can also include a wire-bond and/or horizontal micro-bump coupling the two dies. The heterogeneous integrated circuit can also include a wire bond or vertical micro-bump coupling one of the dies to the package substrate. The vertical micro-bump coupling can include a through-via. The two technologies can be any of various technologies including CMOS, glass, sapphire and quartz. One die can also be adjacent to the other die on the same tier and the two dies coupled using a horizontal micro-bump.

Abstract: In one embodiment, a preliminary solder layer made of a Sn alloy is formed on a connecting pad of a wiring substrate. A solder bump made of a Sn alloy is formed on an electrode pad of a semiconductor chip. After contacting the preliminary solder layer and the solder bump, the preliminary solder layer and the solder bump are melted by heating to a temperature of their melting points or higher to form a solder connecting part made of a Sn alloy containing Ag and Cu. Only the preliminary solder layer of the preliminary solder layer and the solder bump is composed of a Sn alloy containing Ag.

Abstract: An IC package primarily includes a chip, a plurality of electrical connecting components, and a chip carrier including a substrate, a die-attaching layer, and at least one bonding wire. The substrate has a top surface and a bottom surface wherein the top surface includes a die-attaching area for being disposed with the die-attaching layer. The chip is attached to the die-attaching area by the die-attaching layer and is electrically connected to the substrate by the electrical connecting components. Both ends of the bonding wire are bonded respectively to two interconnecting fingers on the top surface of the substrate, and at least a portion of the bonding wire is encapsulated in the die-attaching layer such that some wirings or vias formed on a conventional substrate are not needed. Therefore, the substrate can have a simpler structure and fewer numbers of wiring layers; consequently, the substrate cost can be reduced.

Abstract: A microelectronic assembly including a first and second microelectronic elements. Each of the microelectronic elements have oppositely-facing first and second surfaces and edges bounding the surfaces. The first microelectronic element is disposed on the second microelectronic element with the second surface of the first microelectronic element facing toward the first surface of the second microelectronic element. The first microelectronic element preferably extends beyond at least one edge of the second microelectronic element and the second microelectronic element preferably extends beyond at least one edge of the first microelectronic element.

Abstract: A multifunction card device has an external connection terminal, an interface controller, a memory, and the security controller connected to the interface controller and the external connection terminal. The interface controller has a plurality of interface control modes, and controls an external-interface action and a memory interface action by the control mode according to the instruction from the outside. The external connection terminals have an individual terminal individualized for every interface control mode, and a communalized common terminal. A clock input terminal, a power supply terminal, and an earthing terminal are included in the common terminals. A data terminal, and a dedicated terminal of the security controller are included in the individual terminals. Partial communalization and individualization of an external connection terminal attain a guarantee of the reliability of an interface, and increase control of physical magnitude to some kinds of interface control modes.

Abstract: An embodiment of the invention provides a chip package, which includes: a substrate having an upper surface and a lower surface; a passivation layer located overlying the upper surface of the substrate; a plurality of conducting pad structures disposed overlying the upper surface of the substrate, wherein at least portions of upper surfaces of the conducting pad structures are exposed; a plurality of openings extending from the upper surface towards the lower surface of the substrate; and a plurality of movable bulks located between the openings and connected with the substrate, respectively, wherein each of the movable bulks is electrically connected to one of the conducting pad structures.

Abstract: A method and system for reducing the inductance on an integrated circuit. The method and system comprises providing a first differential line, including a first input and a first output, the first differential line including at least two bondwire traces which are coupled in parallel. The method and system also comprises providing a second differential line including a second input and a second output, the second differential line including at least two bondwire traces which are coupled in parallel, the first differential line being of opposite polarity to the second differential line. The method and system further comprises cross-coupling of the first input with the second input and the first output with the second output to reduce the inductance caused by bondwire traces. A technique in accordance with the invention uses the coupling factor K to help to further reduce the inductance.

Abstract: In accordance with one embodiment, a failure prognostic package includes a substrate having a first surface and an opposite second surface. An electronic component trace is coupled to the first surface. An electronic component is electrically coupled to the electronic component trace. A prognostic trace is coupled to the first surface of the substrate and is electrically isolated from the electronic component. A failure zone of the failure prognostic package includes a plurality of sides and a plurality of corners, wherein the prognostic trace is weaker at the failure zone than the electronic component trace. Failure of the prognostic trace does not cause failure of the failure prognostic package. However, failure of the prognostic trace provides advanced notice of failure of the failure prognostic package.