Abstract: A compound screw is a two-piece assembly where the head of the screw can rotate in the tightening direction to a designed tightening torque to drive the screw while being able to positively counter-rotate in the loosening direction. The screw assembly comprises a screw and a cap surrounding the head of the screw. The screw has a head at the top and a threaded shank downwardly extending from a base of the screw head. The screw is turned by turning the cap about a central axis of the screw. The cap is rotatably affixed to the screw head by a loose riveting of the cap to the top most end of the screw head by flaring a thin-walled upwardly extending portion thereof. The cap includes a plurality of axially extending peripheral resilient arms which engage peripheral cam surfaces around the outside of the screw head.

Abstract: Disclosed are a printed circuit board and a method of manufacturing the printed circuit board. The printed circuit board includes an insulating layer, and a circuit pattern formed on the insulating layer, wherein the circuit pattern includes a first circuit pattern formed on the insulating layer and including a corner portion of an upper portion which has a predetermined curvature and a second circuit pattern formed on the first circuit pattern and configured to cover an upper surface of the first circuit pattern including the corner portion.

Abstract: A semiconductor device includes a die coupled to a substrate, a first memory device coupled to a surface of the die opposite the substrate and a coupling device coupled between the surface of the die opposite the substrate and a second memory device such that the second memory device at least partially overlaps the first memory device. Also disclosed is method of mounting first and second memory devices on a die in an at least partially overlapping manner.

Abstract: A package on package structure includes a connection substrate having a main body and electrically conductive posts, the main body includes a first surface and an opposite second surface, and each electrically conductive post passes through the first and second surfaces, and each end of the two ends of the electrically conductive post protrudes from the main body; a first package device arranged on a side of the first surface of the connection substrate; a package adhesive arranged on a side of the second surface of the connection substrate; and a second package device arranged on a side of the package adhesive furthest away from the first package device.

Abstract: An SMT LED device includes an LED and a circuit board carrying the LED. The circuit board has two copper pads thereon, each being provided with a solder on an inner later side thereof which faces the other copper pad. The LED includes two pins and each pin includes a horizontal protrusion and a vertical portion. The LED is mounted on the circuit board between the two copper pads. The solders securely and electrically connect the two pins of the LED with the circuit board.

Abstract: A semiconductor package includes: a metal plate including a first surface, a second surface and a side surface; a semiconductor chip on the first surface of the metal plate, the semiconductor chip comprising a first surface, a second surface and a side surface; a first insulating layer that covers the second surface of the metal plate; a second insulating layer that covers the first surface of the metal plate, and the first surface and the side surface of the semiconductor chip; and a wiring structure on the second insulating layer and including: a wiring layer electrically connected to the semiconductor chip; and an interlayer insulating layer on the wiring layer. A thickness of the metal plate is thinner than that of the semiconductor chip, and the side surface of the metal plate is covered by the first insulating layer or the second insulating layer.

Abstract: A semiconductor device includes a semiconductor die. An encapsulant is deposited over the semiconductor die. A conductive micro via array is formed outside a footprint of the semiconductor die and over the semiconductor die and encapsulant. A first through-mold-hole (TMH) is formed including a step-through-hole structure through the encapsulant to expose the conductive micro via array. An insulating layer is formed over the semiconductor die and the encapsulant. A micro via array is formed through the insulating layer and outside the footprint of the semiconductor die. A conductive layer is formed over the insulating layer. A conductive ring is formed comprising the conductive micro via array. A second TMH is formed partially through the encapsulant to a recessed surface of the encapsulant. A third TMH is formed through the encapsulant and extending from the recessed surface of the encapsulant to the conductive micro via array.

Abstract: According to this disclosure, a method of manufacturing an electronic device is provided, which includes exposing a top surface of a first electrode of a first electronic component to organic acid, irradiating the top surface of the first electrode exposed to the organic acid with ultraviolet light, and bonding the first electrode and a second electrode of a second electronic component by heating and pressing the first electrode and the second electrode each other.

Abstract: A multi-wavelength semiconductor laser device includes a block having a V-shaped groove with two side faces extending in a predetermined direction; and laser diodes with different light emission wavelengths mounted on the side faces of the groove in the block so that their laser beams are emitted in the predetermined direction.

Abstract: Provided are semiconductor devices with a through electrode and methods of fabricating the same. The methods may include forming a via hole at least partially penetrating a substrate, the via hole having an entrance provided on a top surface of the substrate, forming a via-insulating layer to cover conformally an inner surface of the via hole, forming a buffer layer on the via-insulating layer to cover conformally the via hole provided with the via-insulating layer, the buffer layer being formed of a material whose shrinkability is superior to the via-insulating layer, forming a through electrode to fill the via hole provided with the buffer layer, and recessing a bottom surface of the substrate to expose the through electrode.

Abstract: According to this disclosure, a method of manufacturing an electronic device is provided, which includes exposing a top surface of a first electrode of a first electronic component to organic acid, irradiating the top surface of the first electrode exposed to the organic acid with ultraviolet light, and bonding the first electrode and a second electrode of a second electronic component by heating and pressing the first electrode and the second electrode each other.

Abstract: A semiconductor device has a wiring substrate, a first semiconductor chip, a second semiconductor chip, and a sealing member. The second semiconductor chip has a chip-layered structure with a plurality of semiconductor chip components stacked in the height direction of the semiconductor device. The first semiconductor chip has an upper surface located at the same height from a surface of the wiring substrate as an upper surface of the second semiconductor chip.

Abstract: In a semiconductor apparatus, a plurality of semiconductor chips including through-silicon vias are stacked in a vertical direction, wherein the through-silicon via formed in each semiconductor chip protrudes beyond heights of each semiconductor chip.

Abstract: Microelectronic devices having intermediate contacts, and associated methods of packaging microelectronic devices with intermediate contacts, are disclosed herein. A packaged microelectronic device configured in accordance with one embodiment of the invention includes a microelectronic die attached to an interconnecting substrate. The microelectronic die includes an integrated circuit electrically coupled to a plurality of terminals. Each of the terminals is electrically coupled to a corresponding first contact on the die with an individual wire-bond. Each of the first contacts on the die is electrically coupled to a corresponding second contact on the interconnecting substrate by a conductive coupler such as a solder ball.

Abstract: A multi-wavelength semiconductor laser device includes a block having a rectangular groove with a bottom face and two side faces extending in a predetermined direction; and laser diodes with different light emission wavelengths mounted on the bottom face and the side faces of the groove in the block so that their laser beams are emitted in the predetermined direction.

Abstract: An integrated circuit apparatus is provided with package-level connectivity, between internal electronic circuitry thereof and contact points on a package substrate thereof, without requiring top metal pads or bonding wires.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a base carrier; providing a first integrated circuit having a first integrated circuit inactive side and a first integrated circuit active side; coupling a second integrated circuit, having a second integrated circuit inactive side and a second integrated circuit active side, to the first integrated circuit in an active-to-active configuration; attaching the first integrated circuit over the base carrier; attaching a redistribution structure over the first integrated circuit; and forming a base encapsulation over the redistribution structure, the base encapsulation having a recess partially exposing the redistribution structure.

Abstract: A resin sealing method of a semiconductor device includes: positioning semiconductor devices at predetermined positions of an adhesive layer formed on a support body and adhering the semiconductor devices thereto, sealing a part of each of the semiconductor devices with resin by curing a first seal resin in a fluidization state so as to fix the semiconductor devices adhered to the predetermined positions of the adhesive layer formed on the support body, setting the semiconductor devices fixed to the predetermined positions of the adhesive layer formed on the support body in a mold and sealing the exposure parts of the semiconductor devices exposed from the first seal resin with a second seal resin, and removing the support body and the adhesive layer from the semiconductor devices sealed with the resin.

Abstract: A semiconductor device has a semiconductor die. An encapsulant is formed over the semiconductor die. A conductive micro via array is formed over the encapsulant outside a footprint of the semiconductor die. A first through-mold-hole having a step-through-hole structure is formed through the encapsulant to expose the conductive micro via array. In one embodiment, forming the conductive micro via array further includes forming an insulating layer over the encapsulant and the semiconductor die, forming a micro via array through the insulating layer outside the footprint of the semiconductor die, and forming a conductive layer over the insulating layer. In another embodiment, forming the conductive micro via array further includes forming a conductive ring.

Abstract: Proposed is a package structure having a micro-electromechanical (MEMS) element, including a chip having a plurality of electrical connecting pads and a MEMS element formed thereon; a lid disposed on the chip for covering the MEMS element; a stud bump disposed on each of the electrical connecting pads; an encapsulant formed on the chip with part of the stud bumps being exposed from the encapsulant; and a metal conductive layer formed on the encapsulant and connected to the stud bumps. The invention is characterized by completing the packaging process on the wafer directly to enable thinner and cheaper package structures to be fabricated within less time. This invention further provides a method for fabricating the package structure as described above.

Abstract: A wafer structure (88) includes a device wafer (20) and a cap wafer (60). Semiconductor dies (22) on the device wafer (20) each include a microelectronic device (26) and terminal elements (28, 30). Barriers (36, 52) are positioned in inactive regions (32, 50) of the device wafer (20). The cap wafer (60) is coupled to the device wafer (20) and covers the semiconductor dies (22). Portions (72) of the cap wafer (60) are removed to expose the terminal elements (28, 30). The barriers (36, 52) may be taller than the elements (28, 30) and function to prevent the portions (72) from contacting the terminal elements (28, 30) when the portions (72) are removed. The wafer structure (88) is singulated to form multiple semiconductor devices (89), each device (89) including the microelectronic device (26) covered by a section of the cap wafer (60) and terminal elements (28, 30) exposed from the cap wafer (60).

Abstract: A die structure and a die connecting method using the same are provided. The die structure includes a die and a bump structure. The bump structure includes a body and a solder layer. The body is disposed on the die. The solder layer is disposed on the body. The method includes providing a die structure mentioned above, providing a circuit board mentioned above, and soldering the solder layer of the die structure with the tine layer on the copper block of the circuit board. In different embodiments, a tin layer is omitted from the circuit board, wherein the solder layer of the die structure is directly soldered onto the surface of the copper block.

Abstract: A method of manufacturing a package module structure of a high power device using a metal substrate that can improve reliability by minimizing stress due to a thermal expansion coefficient difference between a metal substrate and a semiconductor device includes: preparing a metal substrate; forming an oxide layer by selectively anodizing the metal substrate; forming a mounting groove for mounting a semiconductor device by etching a portion of the oxide layer; installing a shock-absorbing substrate that is made of a material having a thermal expansion coefficient in a range similar to a material of a semiconductor device to expose the entirety or a portion of a bottom portion of the mounting groove; mounting the semiconductor device in the shock-absorbing substrate exposed to the mounting groove; and electrically connecting an electrode terminal of the semiconductor device and an electrode line formed in an upper surface of the oxide layer.

Abstract: A method for fabricating a stacked semiconductor system with encapsulated through wire interconnects includes providing a substrate having a first side, a second side and a substrate contact; forming a via in the substrate contact and the substrate to the second side; placing a wire in the via; forming a first contact on the wire proximate to the first side and a second contact on the wire proximate to the second side; and forming a polymer layer on the first side leaving the first contact exposed. The method also includes stacking two or more substrates and electrically connecting the through wire interconnects on the substrates.

Abstract: A semiconductor device has a base substrate having a plurality of metal traces. A conductive polymer cover is provided having an opening. The conductive polymer cover forms a cavity when attached to the base substrate. At least one die is attached to an interior surface of the conductive polymer cover and positioned over the opening. The conductive polymer cover and the at least one die are electrically coupled to metal traces on the first surface of the base substrate.

Abstract: A multi-wavelength semiconductor laser device includes a block having a rectangular groove with a bottom face and two side faces extending in a predetermined direction; and laser diodes with different light emission wavelengths mounted on the bottom face and the side faces of the groove in the block so that their laser beams are emitted in the predetermined direction.

Abstract: Microelectronic devices having intermediate contacts, and associated methods of packaging microelectronic devices with intermediate contacts, are disclosed herein. A packaged microelectronic device configured in accordance with one embodiment of the invention includes a microelectronic die attached to an interconnecting substrate. The microelectronic die includes an integrated circuit electrically coupled to a plurality of terminals. Each of the terminals is electrically coupled to a corresponding first contact on the die with an individual wire-bond. Each of the first contacts on the die is electrically coupled to a corresponding second contact on the interconnecting substrate by a conductive coupler such as a solder ball.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a substrate; attaching an integrated circuit device to the substrate; forming a stud interconnect having stacked studs, the stud interconnect on the substrate and having a contact surface and a crown surface on an end of the stud interconnect opposite the substrate; applying an encapsulation over the integrated circuit die, over the stud interconnect, and over the substrate; and forming a cavity in the encapsulation over the stud interconnect, the contact surface and the crown surface exposed in the cavity.

Abstract: An integrated circuit structure includes a semiconductor substrate having a front side and a backside. A through-silicon via (TSV) penetrates the semiconductor substrate. The TSV has a back end extending to the backside of the semiconductor substrate. A redistribution line (RDL) is over the backside of the semiconductor substrate and connected to the back end of the TSV. A silicide layer is over and contacting the RDL.

Abstract: A 4D device comprises a 2D multi-core logic and a 3D memory stack connected through the memory stack sidewall using a fine pitch T&J connection. The 3D memory in the stack is thinned from the original wafer thickness to no remaining Si. A tounge and groove device at the memory wafer top and bottom surfaces allows an accurate stack alignment. The memory stack also has micro-channels on the backside to allow fluid cooling. The memory stack is further diced at the fixed clock-cycle distance and is flipped on its side and re-assembled on to a template into a pseudo-wafer format. The top side wall of the assembly is polished and built with BEOL to fan-out and use the T&J fine pitch connection to join to the 2D logic wafer. The other side of the memory stack is polished, fanned-out, and bumped with C4 solder. The invention also comprises a process for manufacturing the device.

Abstract: A semiconductor module system includes a module substrate and first and second semiconductor components stacked on the module substrate. The stacked semiconductor components include through wire interconnects that form an internal signal transmission system for the module system. Each through wire interconnect includes a via, a wire in the via and first and second contacts on the wire.

Abstract: Proposed is a package structure having a micro-electromechanical (MEMS) element, including a chip having a plurality of electrical connecting pads and a MEMS element formed thereon; a lid disposed on the chip for covering the MEMS element; a stud bump disposed on each of the electrical connecting pads; an encapsulant formed on the chip with part of the stud bumps being exposed from the encapsulant; and a metal conductive layer formed on the encapsulant and connected to the stud bumps. The invention is characterized by completing the packaging process on the wafer directly to enable thinner and cheaper package structures to be fabricated within less time. This invention further provides a method for fabricating the package structure as described above.

Abstract: The present invention relates to a connecting structure between semiconductor device 1 of a BGA type which has external electrode terminals 9 including column-like electrode 17, insulating layer 16 formed around the column-like electrode 17 and annular electrode 15 formed around the insulating layer 16, and a printed wiring board capable of mounting the semiconductor device 1 and including lower-layer electrode 28 to be soldered to column-like electrode 17 of the aforementioned external electrode terminal 9 and upper-layer electrode 27 to be soldered to annular electrode 15 of the aforementioned external electrode terminal 9. Column-like electrode 17 of semiconductor device 1 is soldered to lower-layer electrode 28 of printed wiring board 2. Annular electrode 15 of semiconductor device 1 is soldered to upper-layer electrode 27 of printed wiring board 2.

Abstract: A method for fabricating a semiconductor component with an encapsulated through wire interconnect includes the steps of providing a substrate having a first side, a second side and a substrate contact; forming a via in the substrate contact and the substrate to the second side; placing a wire in the via; forming a first contact on the wire proximate to the first side and a second contact on the wire proximate to the second side; and forming a polymer layer on the first side leaving the first contact exposed. The polymer layer can be formed using a film assisted molding process including the steps of: forming a mold film on tip portions of the bonding members, molding the polymer layer, and then removing the mold film to expose the tip portions of the bonding members. The through wire interconnect provides a multi level interconnect having contacts on opposing sides of the semiconductor substrate.

Abstract: A semiconductor device has a package structure provided with leads that are external connection terminals. A base substance is an island, and at least the surface thereof is formed of a conductive material. A semiconductor substrate is mounted on the surface of the base substance, and a ground potential is supplied from the surface of the base substance. A shunt capacitor is provided with an electrode pair of a first electrode and a second electrode formed in parallel, and mounted with the first electrode being electrically connected to the surface of the base substance. An internal bonding wire connects a pad provided on the semiconductor substrate for external connection, to the second electrode of the shunt capacitor. The lead is the external connection terminal of the semiconductor device. An external bonding wire connects the lead to the second electrode of the shunt capacitor.

Abstract: Disclosed is a structure for mounting a component to a lighting device, including at least one lighting-device base, at least one metal film, and a lighting array chip. The lighting-device base has a surface to which a first layer of metal bonding agent is applied. The metal film has a surface attached to the first metal bonding agent layer on the surface of the lighting-device base. The lighting array chip has a bottom surface to which a second layer of metal bonding agent is applied. The second metal bonding agent layer is further attached to an opposite surface of the metal film so as to securely mount the lighting array chip to the surface of the lighting-device base.

Abstract: On the lower surface of a semiconductor construct having an external connection electrode, there are formed an insulating film having a planar size greater than that of the semiconductor construct, and a metal layer and a mask metal layer having a connection pad portion in which a first opening corresponding to the external connection electrode is formed. A laser beam is applied using the mask metal layer as a mask, and a second opening is thereby formed in a part of the insulating film corresponding to the external connection electrode. Then, a connection conductor is formed to connect a wiring line to the external connection electrode via the second opening of the insulating film.

Abstract: A multi-chip module suitable for use in a battery protection circuit. The multi-chip module includes an integrated circuit chip, a first power transistor, a second power transistor, a first connection structure electrically coupling the integrated circuit chip to the first power transistor, a second connection structure electrically coupling the integrated circuit chip to the second power transistor, and a leadframe structure comprising a first lead, a second lead, a third lead and a fourth lead, wherein the integrated circuit chip, the first power transistor, and the second power transistor are mounted on the leadframe structure. A molding material covers at least part of the integrated circuit chip, the first power transistor, the second power transistor, the first connection structure, and the second connection structure.

Abstract: An integrated circuit includes N plane-like metal layers. A first plane-like metal layer includes M contact portions that communicate with the N plane-like metal layers, respectively. The first plane-like metal layer and the N plane-like metal layers are located separate planes. First and second drain regions have a symmetric shape across at least one of horizontal and vertical centerlines. First and second gate regions have a first shape that surrounds the first and second drain regions, respectively. First and second source regions are arranged adjacent to and on one side of the first gate region, the second gate region and the connecting region. The first source region, the second source region, the first drain region and the second drain region communicate with at least two of the N plane-like metal layers.

Abstract: Methods are provided for fabricating a semiconductor device. A method forms a conductive fin arrangement on a first region of a semiconductor substrate. The method continues by forming a semiconductive resistor structure on a second region of the semiconductor substrate after forming the conductive fin arrangement, and forming a gate stack foundation structure overlying the conductive fin arrangement after forming the semiconductive resistor structure. The method removes portions of the gate stack foundation structure overlying the first region of the semiconductor substrate to define a gate structure for the semiconductor device.

Abstract: A premold housing for accommodating a chip structure includes a first part of the housing which is connected to the chip structure as well as connected in an elastically deflectable manner to an additional part of the housing which is fastened to the support structure bearing the entire housing. A mechanism is provided for damping the deflection of the first part of the housing which is connected to the chip structure.

Abstract: An apparatus and a method for producing three-dimensional integrated circuit packages. In one embodiment, an electronics package with at least two dice are stacked one atop another is disclosed. A top die is of smaller size compared with a bottom die such that after a die attach operation, wire-bond pads of the bottom die will be exposed for a subsequent wire bonding operation. The bottom die contains contact pads on the front side that couple with one or more passive components fabricated on the back side of the top die to complete the circuit. In another exemplary embodiment, a method to form one or more three-dimensional passive components in a stacked-die package is disclosed wherein partial inductor elements are fabricated on the front side of the bottom die and the back side of the top die. The top and bottom elements are coupled together completing the passive component.

Abstract: A semiconductor package with enhanced mobility of ball terminals is revealed. A chip is attached to the substrate by a die-attaching material where the substrate has at least a stepwise depression on the covered surface to make the substrate thickness be stepwise decreased from a central line of the die-attaching area toward two opposing sides of the substrate. The die-attaching material is filled in the stepwise depression. Therefore, the thickness of the die-attaching material under cross-sectional corner(s) of the chip becomes thicker so that a row of the ball terminals away from the central line of the die-attaching area can have greater mobility without changing the appearance, dimensions, thicknesses of the semiconductor package, nor the placing plane of the ball terminals. Accordingly, the row of ball terminals located adjacent the edges or corners of the semiconductor package can withstand larger stresses without ball cracks nor ball drop.

Abstract: A semiconductor module includes a first metal foil; an insulating sheet mounted on a top surface of the first metal foil; at least one second metal foil mounted on a top surface of the insulating sheet; at least one semiconductor device mounted on the second metal foil; and a resin case for surrounding the first metal foil, insulating sheet, second metal foil, and semiconductor device. A bottom end of a peripheral wall of the resin case is located above a bottom surface of the first metal foil. A resin is provided inside the resin case to fill the inside of the resin case. The bottom surface of the first metal foil and the resin form a flat bottom surface so that the flat bottom surface contacts an external mounting member.

Abstract: A method for fabricating a semiconductor component with an encapsulated through wire interconnect includes the steps of providing a substrate having a first side, a second side and a substrate contact; forming a via in the substrate contact and the substrate to the second side; placing a wire in the via; forming a first contact on the wire proximate to the first side and a second contact on the wire proximate to the second side; and forming a polymer layer on the first side leaving the first contact exposed. The polymer layer can be formed using a film assisted molding process including the steps of: forming a mold film on tip portions of the bonding members, molding the polymer layer, and then removing the mold film to expose the tip portions of the bonding members. The through wire interconnect provides a multi level interconnect having contacts on opposing sides of the semiconductor substrate.

Abstract: A multi-chip module suitable for use in a battery protection circuit. The multi-chip module includes an integrated circuit chip, a first power transistor, a second power transistor, a first connection structure electrically coupling the integrated circuit chip to the first power transistor, a second connection structure electrically coupling the integrated circuit chip to the second power transistor, and a leadframe structure comprising a first lead, a second lead, a third lead and a fourth lead, wherein the integrated circuit chip, the first power transistor, and the second power transistor are mounted on the leadframe structure. A molding material covers at least part of the integrated circuit chip, the first power transistor, the second power transistor, the first connection structure, and the second connection structure.

Abstract: A semiconductor device has a chip, a first bump electrode, a conductive wire and a second bump electrode. The chip has at least one contact pad, and the first bump electrode is formed on the contact pad. The conductive wire is disposed on an active surface of the chip and electrically connected to the first bump electrode. The second bump electrode is formed on the conductive wire, and the second bump electrode is not disposed over any contact pad of the chip. In addition, a method for packaging a chip and an IC package are also disclosed.

Abstract: This application relates to a semiconductor device, the semiconductor device comprising a metal carrier, an insulating foil partially covering the metal carrier, a first chip attached to the metal carrier over the insulating foil, and a second chip attached to the metal carrier over a region not covered by the insulating foil.

Abstract: An integrated circuit package system is provided providing a first structure, forming a compression via in the first structure, forming a stud bump on a second structure and pressing the stud bump into the compression via forming a mechanical bond.

Abstract: A substrate includes a inorganic material base board has a recess and at least one penetration hole provided around the recess, and a semiconductor device accommodated in the recess and including at least one electrode pad provided on a surface of the semiconductor device. A resin filling is provided in the at least one penetration hole and has at least one through-hole for electrically connecting a top surface and a back surface of the resin filling. An insulating layer covers the surfaces of the semiconductor device, the resin filling and the inorganic material base board and has a first opening corresponding to the at least one through-hole and a second opening corresponding to the at least one electrode pad. A conductive wiring is formed on a surface of the insulating layer for electrically connecting the at least one through-hole and the at least one electrode pad.