Abstract: A semiconductor device comprising: a lower semiconductor package that comprises a first set of one or more semiconductor dies, an upper semiconductor package that is stacked on the lower semiconductor package, the upper semiconductor package comprises a second set of one or more semiconductor dies, and a first interconnect pad that is embedded in a top side of the lower semiconductor package to couple the upper semiconductor package to the lower semiconductor package.

Abstract: In an electronic component mounting structure, a semiconductor element (an electronic component) provided with an electrode pad and a board provide with an electrode pad corresponding to the electrode pad are connected via a conductive material portion. On a surface of the board, there is formed solder resist having an opening regulating an area of the electrode pad. The conductive material portion is formed to protrude from a surface of the solder resist. An elastic coefficient of the conductive material portion is lower than that of the solder resist. A solder bump and the conductive material portion are connected via a metal layer. The conductive material portion is formed to have an area larger than that of the opening of the solder resist. An edge of the conductive material portion is adhered to a portion of the surface of the solder resist. Thus, in a case of mounting an electronic component on a board by flip-chip connection, a reliability of connection can be secured.

Abstract: Disclosed herein is a semiconductor package module. The semiconductor package module includes a circuit substrate having an external connection pattern; electronic components mounted on the circuit substrate; a molding structure having a structure surrounding the circuit substrate so as to seal the electronic components from the external environment; and an external connection structure of which one portion is connected to the external connection pattern and the other portion is exposed to the outside of the molding structure.

Abstract: A semiconductor device may include a lower semiconductor package including at least one lower semiconductor chip, at least one upper semiconductor package mounted on the lower semiconductor package to include at least one upper semiconductor chip, a molding layer provided between the lower and upper semiconductor packages, and connection solder balls provided in the molding layer to electrically connect the lower and upper semiconductor packages to each other. Each of the connection solder balls may include a portion protruding upward from the molding layer, and there may be no gap between the connection solder balls and the molding layer.

Abstract: Package on package (PoP) devices and methods of packaging semiconductor dies are disclosed. A PoP device is formed by connecting a top package and a bottom package together using a plurality of PoP connectors on the bottom package connected to corresponding connectors of the top package. The PoP device further comprises a plurality of dummy connectors contained in the bottom package and not connected to any corresponding connector in the top package.

Abstract: A semiconductor package includes: a first insulating layer; a plurality of first conductive elements disposed in the first insulating layer; a first circuit layer formed on the first insulating layer; a semiconductor chip disposed on the first insulating layer; and an encapsulant formed on the first insulating layer and encapsulating the semiconductor chip. The first conductive elements that are bonding wires have a small diameter and thus occupy desired limited space on the first insulating layer. Therefore, more space is available for the first circuit layer.

Abstract: A structure includes a substrate having a plurality of balls, a semiconductor chip, and an interposer electrically connecting the substrate and the semiconductor chip. The interposer includes a first side, a second side opposite the first side, at least one first exclusion zone extending through the interposer above each ball of the plurality of balls, at least one active through via extending from the first side of the interposer to the second side of the interposer, wherein the at least one active through via is formed outside the at least one first exclusion zone and wherein no active through vias are formed within the at least one first exclusion zone, and at least one dummy through via extending from the first side of the interposer to the second side of the interposer, wherein the at least one dummy through via is formed within the at least one first exclusion zone.

Abstract: First and second bond elements, e.g., wire bonds, electrically connect a chip contact with one or more substrate contacts of a substrate, and can be arranged so that the second bond element is joined to the first bond element at each end and so that the second bond element does not touch the chip contact or one or more substrate contacts. A third bond element can be joined to ends of the first and second bond elements. In one embodiment, a bond element can have a looped connection, having first and second ends joined at a first contact and a middle portion joined to a second contact.

Abstract: A semiconductor device, which exhibits an increased design flexibility for a capacitor element, and can be manufactured with simple method, is provided. A semiconductor device 100 includes: a silicon substrate 101; an interlayer film 103 provided on the silicon substrate 101; a multiple-layered interconnect embedded in the interlayer film 103; a flip-chip pad 111, provided so as to be opposite to an upper surface of an uppermost layer interconnect 105 in the multiple-layered interconnect and having a solder ball 113 for an external coupling mounted thereon; and a capacitance film 109 provided between said uppermost layer interconnect 105 and the flip-chip pad 111. Such semiconductor device 100 includes the flip-chip pad 111 composed of an uppermost layer interconnect 105, a capacitive film 109 and a capacitor element 110.

Abstract: A semiconductor device includes a substrate having a first surface and an opposite second surface. An electrode extends within the substrate towards the first surface and has a protruding portion extending from the first surface. A supporting portion extends from the first surface of the substrate to a sidewall of the protruding portion and supports the protruding portion.

Abstract: A semiconductor wafer has a first conductive layer formed over its active surface. A first insulating layer is formed over the substrate and first conductive layer. A second conductive layer is formed over the first conductive layer and first insulating layer. A UBM layer is formed around a bump formation area over the second conductive layer. The UBM layer can be two stacked metal layers or three stacked metal layers. The second conductive layer is exposed in the bump formation area. A second insulating layer is formed over the UBM layer and second conductive layer. A portion of the second insulating layer is removed over the bump formation area and a portion of the UBM layer. A bump is formed over the second conductive layer in the bump formation area. The bump contacts the UBM layer to seal a contact interface between the bump and second conductive layer.

Abstract: A semiconductor package structure comprises a substrate, a die bonded to the substrate, and one or more stud bump structures connecting the die to the substrate, wherein each of the stud bump structures having a stud bump and a solder ball encapsulating the stud bump to enhance thermal dissipation and reduce high stress concentrations in the semiconductor package structure.

Abstract: Apparatus for performing dicing of die on wafer interposers. Apparatuses are disclosed for use with the methods of dicing an interposer having integrated circuit dies mounted thereon. An apparatus includes a wafer carrier mounted in a frame and having a size corresponding to a silicon interposer, a fixture mounted to the wafer carrier and comprising a layer of material to provide mechanical support to the die side of the silicon interposer, the fixture being patterned to fill spaces between integrated circuit dies mounted on an interposer; and an adhesive tape disposed on a surface of the fixture for adhering to the surface of a silicon interposer. Additional alternative apparatuses are disclosed.

Abstract: A chip assembly includes a PCB and a chip positioned on the PCB. The PCB includes a number of first bonding pads. Each bonding pad includes two soldering balls formed thereon. The chip includes a number of second bonding pads, and each second bonding pad corresponds to a respective first bonding pad. The two soldering balls of each first bonding pad are electrically connected to a corresponding second bonding pad via two bonding wires, and the bonding wires are bonded to the second corresponding bonding pad by a wedge bonding manner.

Abstract: An interposer includes a substrate having a contact pad structure and a stud operably coupled to the contact pad structure. A solder ball is seated on the contact pad structure and formed around the stud. The stud is configured to regulate a collapse of the solder ball when a top package is mounted to the substrate.

Abstract: A sensor array package can include a sensor disposed on a first side of a substrate. Signal trenches can be formed along the edges of the substrate and a conductive layer can be deposited in the signal trench and can couple to sensor signal pads. Bond wires can be attached to the conductive layers and can be arranged to be below a surface plane of the sensor. The sensor array package can be embedded in a printed circuit board enabling the bond wires to terminate at other conductors within the printed circuit board.

Abstract: An interposer to form a frame around a bottom chip bonded to a package substrate and to standoff a top chip or package for clearance of the bottom chip. The interposer has pins arrayed on a first side which are soldered to the package substrate for reduced interposer z-height and pads arrayed on a second side to which the top package (chip) is bonded. During assembly, the interposer pins may be pressed against pre-soldered pads and the solder reflowed to join the interposer to the package substrate. A top package (chip) is then joined to an opposite side of the interposer to integrate the first and second chips.

Abstract: Methods and apparatuses for wafer level packaging (WLP) semiconductor devices are disclosed. A redistribution layer (RDL) is formed on a first passivation layer in contact with a conductive pad over a surface of a die. The RDL layer is on top of a first region of the first passivation layer. A second passivation layer is formed on the RDL layer with an opening to expose the RDL layer, and over the first passivation layer. An under bump metallization (UBM) layer is formed over the second passivation layer in contact with the exposed RDL layer. A second region of the first passivation layer disjoint from the first region is determined by projecting an outer periphery of a solder ball or other connector onto the surface.

Abstract: A conductive bump structure is formed on a substrate having a plurality of bonding pads and a first insulating layer thereon. The first insulating layer has a plurality of openings formed therein for exposing the bonding pads and a conductive post is formed on the bonding pads exposed through the openings. Therein, a gap is formed between the conductive post and the wall of the opening such that no contact occurs between the conductive post and the first insulating layer, thereby preventing delamination of the conductive bump structure caused by stresses concentrating on an interface of different materials as in the prior art.

Abstract: The invention relates to an electrical connector assembly. The electrical connector assembly includes a main circuit board having a through hole, a processor, and an auxiliary circuit board. The processor includes a chip and a substrate. The chip is electrically connected to the substrate and located in the through hole. The substrate is at least partially located in the through hole. The auxiliary circuit board has a transitional connecting surface. A first conducting region and a second conducting region electrically connected to each other are disposed on the transitional connecting surface. The first conducting region is electrically connected to the substrate, and the second conducting region is electrically connected to the main circuit board.

Abstract: A microelectronic package includes a subassembly including a first substrate and first and second microelectronic elements having contact-bearing faces facing towards oppositely-facing first and second surfaces of the first substrate and each having contacts electrically connected with the first substrate. The contact-bearing faces of the first and second microelectronic elements at least partially overlie one another. Leads electrically connect the subassembly with a second substrate, at least portions of the leads being aligned with an aperture in the second substrate. The leads can include wire bonds extending through an aperture in the first substrate and joined to contacts of the first microelectronic element aligned with the first substrate aperture. In one example, the subassembly can be electrically connected with the second substrate using electrically conductive spacer elements.

Abstract: Provided is a semiconductor device with a semiconductor chip mounted on a small-sized package substrate that includes a slot, a large number of external connection terminals, and bonding fingers. The bonding fingers are connected to the external connection terminals. The bonding fingers constitute a bonding finger arrangement in a central section and end sections of a bonding finger area along each longer side of the slot. The arrangement includes a first bonding finger array, which is located at a close distance from each longer side of the slot, and a second array, which is located at a farther distance than the distance of the first bonding finger array from each longer side of the slot. The central section of the bonding finger area includes the second bonding finger array, and the end sections of the bonding finger area include the first bonding finger array.

Abstract: A chip package includes a PCB, a chip positioned on the PCB and bonding wires electrically connecting the chip to the PCB. The PCB includes a number of first bonding pads formed thereon. Each first bonding pad includes a first soldering ball. The chip includes a number of second bonding pads. Each second bonding pad includes a second bonding ball. Each bonding wire electrically connects a first bonding pad to a corresponding second bonding ball. Each bonding wire forms a vaulted portion upon the first bonding ball.

Abstract: Methods and apparatus for solder connections. An apparatus includes a substrate having a conductive terminal on a surface; a passivation layer overlying the surface of the substrate and the conductive terminal; an opening in the passivation layer exposing a portion of the conductive terminal; at least one stud bump bonded to the conductive terminal in the opening and extending in a direction normal to the surface of the substrate; and a solder connection formed on the conductive terminal in the opening and enclosing the at least one stud bump. Methods for forming the solder connections are disclosed.

Abstract: A multi-chip semiconductor device comprises a thermally enhanced structure, a first semiconductor chip, a second semiconductor chip, an encapsulation layer formed on top of the first semiconductor chip and the second semiconductor chip. The multi-chip semiconductor device further comprises a plurality of thermal vias formed in the encapsulation layer. The thermally enhanced structure comprises a heat sink block attached to a first semiconductor die. The heat sink block may further comprise a variety of thermal vias and thermal openings. By employing the thermal enhanced structure, the thermal performance of the multi-chip semiconductor device can be improved.

Abstract: An optoelectronic semiconductor component includes a connection support with a connection side, at least one optoelectronic semiconductor chip mounted on the connection side and electrically connected to the connection support, an adhesion-promoting intermediate film applied to the connection side and covering the latter at least in selected places, and at least one radiation-transmissive cast body which at least partially surrounds the semiconductor chip, the cast body being connected mechanically to the connection support by the intermediate film.

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 method for manufacturing a printed wiring board includes forming an uncalcined layer containing a raw ceramic material on a first metal layer, firing the uncalcined layer formed on the first metal layer such that a high dielectric constant layer having a ceramic body calcined in a sheet form is formed on the first metal layer, forming a second metal layer on the high dielectric constant layer on the opposite side of the high dielectric constant layer with respect to the first metal layer such that a layered capacitor having the high dielectric constant layer and first and second layer electrodes sandwiching the high dielectric constant layer is formed, and disposing the layered capacitor in a main body.

Abstract: The invention generally relates to a packaging method of an ultra-thin chip, more specifically, the invention relates to a method for packaging the ultra-thin chip with solder ball thermo-compression in wafer level packaging process. The method starts with disposing solder balls on metal pads arranged on the front surface of semiconductor chips that are formed at the front surface of a semiconductor wafer. The solder balls are soften by heating the wafer, a compression plate is applied with a pressure on the top ends of the solder balls thus forming a co-planar top surface at the top ends of the solder balls. A molding compound is deposited on the front surface of the wafer with the top ends of the solder balls exposed. The wafer is then ground from its back surface to reduce its thickness to achieve ultra-thin chip.

Abstract: A pillar structure for a substrate is provided. The pillar structure may have one or more tiers, where each tier may have a conical shape or a spherical shape. In an embodiment, the pillar structure is used in a bump-on-trace (BOT) configuration. The pillar structures may have circular shape or an elongated shape in a plan view. The substrate may be coupled to another substrate. In an embodiment, the another substrate may have raised conductive traces onto which the pillar structure may be coupled.

Abstract: A semiconductor package comprises a bond pad formed on a first semiconductor die, a surface of the bond pad exposed through an opening in a passivation layer on the first semiconductor die; a raised conductive area formed on top of a passivation layer on a second semiconductor die; and a bond wire having a first end coupled to the bond pad via a ball bond and a second end coupled directly to a surface of the raised conductive area via a stitch bond. The raised conductive area is comprised of a plurality of metal layers, each of the metal layers comprised of a respective material and having a respective thickness. The thickness and material of at least one of the plurality of metal layers is selected such that a hardness of the raised conductive area is at least as hard as a hardness of the bond wire.

Abstract: The described embodiments of mechanisms of forming a package on package (PoP) structure involve bonding with connectors with non-solder metal balls to a packaging substrate. The non-solder metal balls may include a solder coating layer. The connectors with non-solder metal balls can maintain substantially the shape of the connectors and control the height of the bonding structures between upper and lower packages. The connectors with non-solder metal balls are also less likely to result in bridging between connectors or disconnection (or cold joint) of bonded connectors. As a result, the pitch of the connectors with non-solder metal balls can be kept small.

Abstract: A semiconductor device includes a semiconductor die having first and second conductive pads, and a substrate having third and fourth bonding pads. A width ratio of the first conductive pad over the third bonding pad at an inner region is different from a width ratio of the second conductive pad over the fourth bonding pad at an outer region.

Abstract: A semiconductor package includes a first semiconductor chip having first bumps which are projectedly formed thereon; a first copper foil attachment resin covered on the first semiconductor chip to embed the first semiconductor chip, and formed such that a first copper foil layer attached on an upper surface of the first copper foil attachment resin is electrically connected with the first bumps; a second copper foil attachment resin including a second copper foil layer which is electrically connected with the first copper foil layer, and disposed on the first copper foil attachment resin; and a second semiconductor chip embedded in the second copper foil attachment resin in such a way as to face the first semiconductor chip, and having second bumps formed thereon which are electrically connected with the second copper foil layer.

Abstract: A packaged microelectronic assembly includes a microelectronic element having a front surface and a plurality of first solid metal posts extending away from the front surface. Each of the first posts has a width in a direction of the front surface and a height extending from the front surface, wherein the height is at least half of the width. There is also a substrate having a top surface and a plurality of second solid metal posts extending from the top surface and joined to the first solid metal posts.

Abstract: A substrate device includes: a plurality of substrates stacked one on another including a substrate on which electronic components are mounted; and a coupling member connecting mechanically and electrically the two opposed substrates, and the coupling member includes: a plurality of core-less solder balls connecting mechanically and electrically the two opposed substrates; and a plurality of spacers configured to keep a clearance between the two opposed substrates wider than a mounting height of the electronic component between the substrates.

Abstract: A semiconductor device is provided comprising: a semiconductor element including a plurality of electrodes; first wirings coupled to the electrodes and directed toward a center of the semiconductor element from a portion coupled to the electrodes; second wirings coupled between the first wirings and external terminals, the second wirings being directed to an outer area of the semiconductor element relative to the center; and at least one resin layer formed between the first wirings and the second wirings.

Abstract: A wafer level fan out package includes a semiconductor die having a first surface, a second surface, and a third surface. A stiffener is disposed on the third surface of the semiconductor die. A conductive via passes through the stiffener. First and second electrically conductive patterns electrically connected to the conductive via are disposed on the first and second surfaces of the semiconductor die and stiffener. Solder balls are electrically connected to the first or second electrically conductive patterns.

Abstract: An electronic component package includes a RDL pattern comprising a redistribution pattern terminal. A buildup dielectric layer is formed on the RDL pattern, the buildup dielectric layer having a redistribution pattern terminal aperture exposing the redistribution pattern terminal. An interconnection ball is formed within the redistribution pattern terminal aperture and on the redistribution pattern terminal. The interconnection ball includes an enclosed portion having an outer concave surface within the buildup dielectric layer. The angle of intersection between the outer concave surface of the interconnection ball and the redistribution pattern is less than 90°. This minimizes stress between the interconnection ball and the redistribution pattern which, in turn, minimizes failure of the bond between the interconnection ball and the redistribution pattern.

Abstract: A stacked semiconductor package includes a semiconductor package module including a plurality of semiconductor packages each of which has a first surface, a second surface facing away from the first surface, side surfaces connecting the first surface and the second surface and through-holes formed on the side surfaces to pass through the first surface and the second surface and which are stacked such that their through-holes vertically connect with one another, and adhesive members which are formed between the semiconductor packages and attach the semiconductor packages to one another, a main substrate supporting the semiconductor package module and formed, on a third surface thereof facing the semiconductor package module, with main connection pads which are aligned with the through-holes, and conductive connection members formed in the through-holes and electrically connecting the semiconductor packages with the main connection pads.

Abstract: Presented is a method for fabricating a semiconductor package, and the associated semiconductor package. The method includes providing a compliant coverlay having a resin film disposed thereon. A plurality of metallic spheres may be placed at predetermined positions in the resin film. A top surface and a bottom surface of the metallic spheres may be flattened. Tamp blocks on opposing sides of the metallic spheres may be used. The resin film may then be cured to permanently set the metallic spheres in the resin film, and the compliant overlay may then be removed. A semiconductor die may then be placed on the plurality of metallic spheres. An encapsulating layer may then be deposited over the semiconductor die, the plurality of metallic spheres, and the resin film. The semiconductor package may then be diced. The method does not include fabricating a metal leadframe for the semiconductor die.

Abstract: In various aspects of the disclosure, a chip packaging arrangement may be provided. The chip packaging arrangement may include a dielectric layer with at least one semiconductor device adjoining the dielectric layer, at least one bonding area on the semiconductor device, the bonding area being exposed through the dielectric layer, a first material comprising a first coefficient of thermal expansion substantially surrounding the semiconductor device and adjoining the dielectric layer, a second material comprising a second coefficient of thermal expansion substantially surrounding the semiconductor device and the first material; and at least one conductive trace electrically connected to the semiconductor device.

Abstract: In various aspects of the disclosure, a package may be provided. The package may include at least one semiconductor device rotated about an axis with respect to an edge of the package, at least one bond pad on each semiconductor device, and at least one conductive trace electrically connected to the semiconductor device through the at least one bond pad.

Abstract: A semiconductor device has a semiconductor substrate which has a plurality of pad electrodes provided on a top surface thereof and has an approximately rectangular shape; a rewiring layer which is provided with a plurality of contact wiring lines connected to the plurality of pad electrodes, is disposed on the semiconductor substrate through an insulating film, and has an approximately rectangular shape; and a plurality of ball electrodes which are provided on the rewiring layer.

Abstract: The invention provides a semiconductor chip structure having at least one aluminum pad structure and a polyimide buffering layer under the aluminum pad structure, wherein the polyimide buffering layer is self-aligned to the aluminum pad structure, and a method of forming the same. The method includes forming a polyimide buffering layer on a substrate, forming an aluminum pad structure on the buffering layer, and, using the aluminum pad structure as a mask, etching the substrate to remove the polyimide buffering layer from the substrate everywhere except under the aluminum pad structure.

Abstract: Provided is a ball grid array substrate, a semiconductor chip package, and a method of manufacturing the same. The ball grid array substrate includes an insulating layer having a first surface providing a mounting region for a semiconductor chip, a second surface opposing the first surface, and an opening connecting the second surface with the mounting region of the semiconductor chip, and a circuit pattern buried in the second surface. Since the ball grid array substrate is manufactured by a method of stacking two insulating layers, existing devices can be used, and the ball grid array substrate can be manufactured as an ultra thin plate. In addition, since the circuit pattern is buried in the insulating layer, a high-density circuit pattern can be formed.

Abstract: A stacked semiconductor package has a first semiconductor package including a first package substrate and a first semiconductor chip mounted on the first package substrate, a second semiconductor package including a second package substrate and a second semiconductor chip mounted on the second package substrate, and a plurality of connections electrically connecting the first and second semiconductor packages. The connections are disposed on an outer region of the first package substrate outside the first semiconductor chip. The connections are disposed along opposite first longer sides and opposite shorter second sides of the first package substrate. The heights of those connections disposed along each longer first side gradually vary from a central to an outer region (i.e., the ends) of the longer first side.

Abstract: A semiconductor device is made by forming solder bumps over a copper carrier. Solder capture indentations are formed in the copper carrier to receive the solder bumps. A semiconductor die is mounted to the copper carrier using a die attach adhesive. The semiconductor die has contact pads formed over its active surface. An encapsulant is deposited over the copper carrier, solder bumps, and semiconductor die. A portion of the encapsulant is removed to expose the solder bumps and contact pads. A conductive layer is formed over the encapsulant to connect the solder bumps and contact pads. The conductive layer operates as a redistribution layer to route electrical signals from the solder bumps to the contact pads. The copper carrier is removed. An insulating layer is formed over the conductive layer and encapsulant. A plurality of semiconductor devices can be stacked and electrically connected through the solder bumps.

Abstract: A resin overcap with an IC tag used as an overcap being on a metal cap and having an IC tag so that the transmission and reception of signals will not be disturbed by the metal cap, comprising a top panel and a cylindrical side wall hanging down from the circumferential edge of the top panel and in which the metal cap is fitted, wherein a step or a protrusion is formed on an upper portion on the inner surface of the cylindrical side wall to prevent the upward motion of the metal cap fitted in the cylindrical side wall, and an IC tag provided with an IC chip is mounted on the top panel to maintain a predetermined distance D to a top plate of the metal cap fitted into the cylindrical side wall.

Abstract: Packaged microelectronic devices recessed in support member cavities, and associated methods, are disclosed. Method in accordance with one embodiment includes positioning a microelectronic device in a cavity of a support member, with the cavity having a closed end with a conductive layer, and an opening through which the cavity is assessable. The microelectronic device can have bond sites, a first surface, and a second surface facing opposite from the first surface. The microelectronic device can be positioned in the cavity so that the second surface faces toward and is carried by the conductive layer. The method can further include electrically coupling the bond sites of the microelectronic device to the conductive layer. In particular embodiments, the microelectronic device can be encapsulated in the cavity without the need for a releasable tape layer to temporarily support the microelectronic device.