Abstract: A method and system for manufacturing a light conversion structure for a light emitting diode (LED) is disclosed. The method includes forming a transparent, thermally insulating cover over an LED chip. The method also includes dispensing a conversion material onto the cover to form a conversion coating on the cover, and encapsulating the LED, the silicone cover, and the conversion coating within an encapsulant. Additional covers and conversion coatings can be added.

Abstract: A light emitting device includes a substrate, a first lead frame and a second lead frame on the substrate, an installation portion electrically connected to the first lead frame or the second lead frame, the installation portion being thinner than the first lead frame or the second lead frames, a light emitting diode on the installation portion, and a conductive member electrically connecting at least one of the lead frames to the light emitting diode.

Abstract: A die package includes a substrate, a die mounted on the substrate, and a ZQ resistor disposed in the die package and connected to the substrate and the die. The ZQ resistor may be used to calibrate impedance of the die.

Abstract: In one aspect of the present invention, an integrated circuit package with an exposed die and a protective housing will be described. The housing extends beyond the exposed back surface of the die to help protect it from damage. The integrated circuit package includes a lead frame and an integrated circuit die. The integrated circuit die is electrically and physically attached to the lead frame. The housing encapsulates the lead frame and the die. The housing also includes a recessed region at the bottom of the package where the back surface of the die is exposed. There is a protruding protective structure at the bottom of the package that helps to protect the die and prevent its exposed back surface from coming in contact with an external object.

Abstract: There is provided a system and method for a copper stud bump wafer level package. There is provided a semiconductor package comprising a semiconductor die having a plurality of bond pads on an top surface thereof, a plurality of metallic stud bumps mechanically and electrically coupled to said plurality of bond pads, and a plurality of solder balls mechanically and electrically coupled to said plurality of metallic stud bumps. Advantageously, the metallic stud bumps may be provided using standard wirebonding equipment, avoiding the conventional wafer level package requirement for photolithography and deposition steps to provide a multi-layer metallic routing structure. As a result, reduced cycle times, lower cost, and reduced complexity may be provided. Alternative fabrication processes utilizing metallic stud bumps may also support multi-die packages with dies from different wafers and packages with die perimeter pads wirebonded to substrates.

Abstract: A process for forming a heat sink on a semiconductor package at the wafer level stage of manufacture is disclosed. A semiconductor component wafer, prior to separation into separate component packages, is covered on one side with a resin metal foil layer. The resin foil layer is patterned by laser ablation to define the heat sink locations, and then a thermal paste is applied over the patterned layer. The thermal conductive past is hardened to form the heat sinks. The wafer can then be separated into packages.

Abstract: Process for encapsulating a micro-device in a cavity formed between one first and one second substrate, comprising at least the steps of: producing the micro-device in and/or on the first substrate, attaching and securing the second substrate to the first substrate, forming the cavity in which the micro-device is placed, producing at least one hole through one of the two substrates, called the drilled substrate, and leading into the cavity opposite a portion of the other of the two substrates, called the receiving substrate, depositing at least one getter material portion on said portion of the receiving substrate through the hole, hermetically sealing the cavity by closing the hole.

Abstract: Structure and method for fabricating a barrier layer that separates an electromechanical device and a CMOS device on a substrate. An example structure includes a protective layer encapsulating the electromechanical device, where the barrier layer may withstand an etch process capable of removing the protective layer, but not the barrier layer. The substrate may be silicon-on-insulator or a multilayer wafer substrate. The electromechanical device may be a microelectromechanical system (MEMS) or a nanoelectromechanical system (NEMS).

Abstract: A downhole tool is described. The downhole tool includes a work device and an electronics packaging connected to the work device. The electronics packaging comprises a housing, a substrate, at least one first type component, and at least one second type component. The housing defines a void. The substrate is positioned within the void of the housing and forms a first cavity and a second cavity relative to the housing. The first cavity and the second cavity are isolated to form separate atmospheric chambers. The at least one first type component is disposed in the first cavity and connected to the substrate. The at least one second type component is disposed in the second cavity and connected to the substrate. The at least one first type component is different from the at least one second type component.

Abstract: A method of manufacture of an integrated circuit packaging system includes: forming a lead having an upper portion and a bottom portion with a first overhang portion from a top surface of the upper portion and the lead also having serrations along upper vertical sides intersecting the top surface; forming an upper contact plate on the top surface; forming a bottom contact plate on a bottom surface of the bottom portion; attaching an integrated circuit die over the upper portion; and encapsulating the upper portion and the integrated circuit die with an encapsulation leaving the bottom portion exposed.

Abstract: A method of making integrated circuit package assemblies including encapsulating a plurality of dies in an encapsulation layer having an exterior surface and attaching a heat sink strip to the exterior surface of the encapsulation layer. An integrated circuit package assembly and an intermediate product used in making an integrated circuit package assembly are also disclosed.

Abstract: This disclosure provides systems, methods and apparatus for fabricating spacers for electromechanical systems devices. In one aspect, a method of forming a spacer on a spacer portion of a device surface of an electromechanical systems device includes exposing the device surface to spacer particles suspended in a fluid. The spacer particles are allowed to attach to the spacer portion. Each of the spacer particles can have at least one dimension of about 1 micron to 10 microns. The electromechanical systems device can also include a sacrificial layer that is subsequently removed between the device surface and a substrate surface of a substrate on which the electromechanical systems device is formed.

Abstract: A packaging substrate includes a holder, a first conductive pad disposed on the holder, a core layer disposed on the holder, a circuit layer disposed on the core layer, a plurality of conductive vias disposed in the core layer, and an insulating protection layer disposed on the core layer, wherein the first electrical pad is embedded in the core layer. By combining the holder on one side of the packaging substrate, cracks due to over-thinness can be prevented during transferring or packaging. A method of fabricating the packaging substrate, a package structure having a holder, a method of fabricating the package structure are also provided.

Abstract: A semiconductor device has a substrate with a plurality of conductive vias formed through the substrate and conductive layer formed over the substrate. A first encapsulant is deposited over the substrate outside a die attach area of the substrate. The first encapsulant surrounds each die attach area over the substrate and the die attach area is devoid of the first encapsulant. A channel connecting adjacent die attach areas is also devoid of the first encapsulant. A first semiconductor die is mounted over the substrate within the die attach area after forming the first encapsulant. A second semiconductor die is mounted over the first die within the die attach area. An underfill material can be deposited under the first and second die. A second encapsulant is deposited over the first and second die and first encapsulant. The first encapsulant reduces warpage of the substrate during die mounting.

Abstract: A process for manufacturing a semiconductor device envisages the steps of: positioning a frame structure, provided with a supporting plate carrying a die of semiconductor material, within a molding cavity of a mold; and introducing encapsulating material within the molding cavity for the formation of a package, designed to encapsulate the die. The frame structure is further provided with a prolongation element mechanically coupled to the supporting plate inside the molding cavity and coming out of the molding cavity, and the process further envisages the steps of: controlling positioning of the supporting plate within the molding cavity with the aid of the prolongation element; and, during the step of introducing encapsulating material, separating and moving the prolongation element away from the supporting plate.

Abstract: A pressure loss section H1 (H2) extends from a position corresponding to a corner of a resin package, and S1 is the minimum value of the opening area of the pressure loss section H1 (H2) perpendicular to the direction of resin flow (X axis) in the pressure loss section H1 (H2) during resin molding, while S2 is the average value of the opening areas of excess resin reservoirs H3 to H5 perpendicular to the direction of resin flow (Y axis) within excess resin reservoir H3 to H5 during molding. In this lead frame, S1<S2 is satisfied.

Abstract: Disclosed is a granular epoxy resin composition for encapsulating a semiconductor used for a semiconductor device obtained by encapsulating a semiconductor element by compression molding, wherein, in the particle size distribution as determined by sieving the whole epoxy resin composition for encapsulating a semiconductor using JIS standard sieves, the ratio of particles having a size of 2 mm or greater is not more than 3% by mass, the ratio of particles having a size of 1 mm or greater, but less than 2 mm is from 0.5% by mass or more to 60% by mass or less, and the ratio of microfine particles having a size of less than 106 ?m is not more than 5% by mass.

Abstract: A method for producing a semiconductor device, including a semiconductor chip, for improving production efficiency and the flexibility of production design is provided.

Abstract: A method of manufacture of an integrated circuit packaging system includes: mounting a device mounting structure over a bottom substrate; mounting a heat spreader having an opening formed by a single integral structure with a dam and a flange, the dam having a dam height greater than a flange height of the flange; and forming a package encapsulation over the device mounting structure and the bottom substrate with the device mounting structure exposed within the opening.

Abstract: A method for producing a semiconductor device for improving production efficiency and the flexibility of production design thereof is provided. The method includes preparing semiconductor chips having a first main surface on which an electroconductive member is formed, preparing a supporting structure in which over a support configured to transmit radiation, a radiation curable pressure-sensitive adhesive layer and a first thermosetting resin layer are laminated in this order, arranging the semiconductor chips on the first thermosetting resin layer to face the first thermosetting resin layer to the first main surfaces of the semiconductor chips, laminating a second thermosetting resin layer over the first thermosetting resin layer to cover the semiconductor chips, and curing the radiation curable pressure-sensitive adhesive layer by irradiating from the support side to peel the radiation curable pressure-sensitive adhesive layer and the first thermosetting resin layer from each other.

Abstract: Integrated circuits and methods of fabricating integrated circuits are disclosed herein. One embodiment of an integrated circuit includes a die having a side, wherein a conductive stud extends from the side. A dielectric layer having a first side and a second side is located proximate the side of the die so that the first side of the dielectric layer is adjacent the side of the die. The conductive stud extends into the first side of the dielectric layer. A conductive layer having a first side and a second side is located adjacent the second side of the dielectric layer, wherein the first side of the conductive layer is located adjacent the second side of the dielectric layer. A conductive adhesive connects the conductive stud to the first side of the conductive layer.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a base substrate; applying a molded under-fill on the base substrate; forming a substrate contact extender through the molded under-fill and in direct contact with the base substrate; mounting a stack device over the molded under-fill; attaching a coupling connector from the substrate contact extender to the stack device; and forming a base encapsulation on the stack device, the substrate contact extender, and encapsulating the coupling connector.

Abstract: A semiconductor device has a semiconductor die mounted to a carrier. An encapsulant is deposited over the semiconductor die and carrier. The carrier is removed. A first insulating layer is formed over the encapsulant and semiconductor die. First vias are formed through the first insulating layer to expose contact pads of the semiconductor die. A first conductive layer is formed over the first insulating layer and into the first vias to electrically connect to the contact pads of the semiconductor die. A second insulating layer is formed over the first insulating layer and first conductive layer. Second vias are formed through the second insulating layer by laser direct ablation and aligned or offset with the first vias to expose the first conductive layer. A second conductive layer is formed over the second insulating layer and into the second vias. Conductive vias can be formed through the encapsulant.

Abstract: A semiconductor package method for co-packaging high-side (HS) and low-side (LS) semiconductor chips is disclosed. The HS and LS semiconductor chips are attached to two opposite sides of a lead frame, with a bottom drain electrode of the LS chip connected to a top side of the lead frame and a top source electrode of the HS chip connected to a bottom side of the lead frame through a solder ball. The stacking configuration of HS chip, lead frame and LS chip reduces the package size. A bottom metal layer covering the bottom of HS chip exposed outside of the package body provides both electrical connection and thermal conduction.

Abstract: Integrated circuits and methods of fabricating integrated circuits are disclosed herein. One embodiment of an integrated circuit includes a die having a side, wherein a conductive stud extends substantially normal relative to the side. A dielectric layer having a first side and a second side is located proximate the side of the die so that the first side of the dielectric layer is adjacent the side of the die. The conductive stud extends into the first side of the dielectric layer. A first via extends between the conductive stud and the second side of the dielectric layer. A conductive layer having a first side and a second side is located adjacent the second side of the dielectric layer, wherein the first side of the conductive layer is located adjacent the second side of the dielectric layer. At least a portion of the conductive layer is electrically connected to the first via.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a package carrier; mounting an integrated circuit to the package carrier; forming an external wire on the package carrier and adjacent to the integrated circuit; forming an encapsulation on the package carrier over the external wire; and forming a hole in the encapsulation with the external wire and a portion of the package carrier exposed from the encapsulation.

Abstract: A method of manufacture of an integrated circuit packaging system includes: forming a peripheral lead having a peripheral contact layer surrounding the peripheral lead with a non-horizontal side exposed from the peripheral contact layer; forming an inner lead and a paddle non-planar with the peripheral lead; mounting an integrated circuit to the paddle; and forming an encapsulation covering the integrated circuit and exposing the inner lead, the paddle, and the non-horizontal side.

Abstract: A circuit board assembly includes a circuit board, a chip attached to the circuit board and a dielectric layer. The chip has a circuit facing the circuit board and spaced from it. The dielectric layer includes an aerogel. In one embodiment, the aerogel has a dielectric constant of approximately 2.0 or less and a compression strength of at least approximately 100 psi.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a base substrate; attaching a base integrated circuit on the base substrate; forming a base encapsulation, having a base encapsulation top side, on the base substrate and around the base integrated circuit; forming a base conductive via, having a base via head, through the base encapsulation and attached to the base substrate adjacent to the base integrated circuit, the base via head exposed from and coplanar with the base encapsulation top side; mounting an interposer structure over the base encapsulation with the interposer structure connected to the base via head; and forming an upper encapsulation on the base encapsulation top side and partially surrounding the interposer structure with a side of the interposer structure facing away from the base encapsulation exposed.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a first substrate; mounting an integrated circuit structure on the first substrate; mounting a second substrate on the integrated circuit structure; coupling a vertical chip to the first substrate and to the second substrate; and forming a package body for encapsulating the integrated circuit structure, the vertical chip, and a portion of the second substrate.

Abstract: Embodiments for multi-chip and multi-substrate reconstitution based packaging are provided. Example packages are formed using substrates from a reconstitution. substrate panel or strip. The reconstitution substrate panel or strip may include known good substrates of same or different material types and/or same of different layer counts and sizes. As such, different combinations of reconstitution substrates and chips can be used within the same package, thereby allowing substrate customization according to semiconductor chip block(s) and types contained in the package.

Abstract: A semiconductor device has a first encapsulant deposited over a first carrier. A plurality of conductive vias is formed through the first encapsulant to provide an interconnect substrate. A first semiconductor die is mounted over a second carrier. The interconnect substrate is mounted over the second carrier adjacent to the first semiconductor die. A second semiconductor die is mounted over the second carrier adjacent to the interconnect substrate. A second encapsulant is deposited over the first and second semiconductor die, interconnect substrate, and second carrier. A first interconnect structure is formed over a first surface of the second encapsulant and electrically connected to the conductive vias. A second interconnect structure is formed over a second surface of the second encapsulant and electrically connected to the conductive vias to make the Fo-WLCSP stackable. Additional semiconductor die can be mounted over the first and second semiconductor die in a PoP arrangement.

Abstract: Circuits and methods of fabricating circuits are disclosed herein. An embodiment of the circuit includes a die having a side, wherein a connection point is located on the side. A dielectric layer having a first side, a second side, and at least one via extending between the first side and the second side, is located proximate the side of the die. The via is electrically connected to the connection point. A conductive layer is located adjacent the second side of the first dielectric layer, wherein at least a portion of the conductive layer is electrically connected to the via.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a substrate having a substrate first side and a substrate second side opposite the substrate first side; attaching a base integrated circuit to the substrate first side; attaching a mountable integrated circuit to the substrate second side; attaching a via base to the substrate second side adjacent the mountable integrated circuit; forming a device encapsulation surrounding the via base and the mountable integrated circuit; and forming a via extension through the device encapsulation and attached to the via base, the via extension exposed from the device encapsulation.

Abstract: The present invention provides a semiconductor device which is formed at low cost and has a great versatility, a manufacturing method thereof, and further a semiconductor device with an improved yield, and a manufacturing method thereof. A structure, which has a base including a plurality of depressions having different shapes or sizes, and a plurality of IC chips which are disposed in the depressions and which fit the depressions, is formed. A semiconductor device which selectively includes a function in accordance with an application, by using the base including the plurality of depressions and the IC chips which fit the depressions, can be manufactured at low cost.

Abstract: A production method for chips, in which as many method steps as possible are carried out in the wafer composite, that is, in parallel for a plurality of chips disposed on a wafer. This is a method for producing a plurality of chips whose functionality is implemented on the basis of the surface layer of a substrate. In this method, the surface layer is patterned and at least one cavity is produced below the surface layer, so that the individual chip regions are connected to each other and/or to the rest of the substrate by suspension webs only, and/or so that the individual chip regions are connected to the substrate layer below the cavity via supporting elements in the region of the cavity. The suspension webs and/or supporting elements are cut when the chips are separated. The patterned and undercut surface layer of the substrate is embedded in a plastic mass before the chips are separated.

Abstract: Disclosed are a flip-chip carrier having individual pad masks (IPMs) and a fabricating method of a MPS-C2 package utilized from the same. The flip-chip carrier primarily comprises a substrate and a plurality of the IPMs. The substrate has a top surface and a plurality of connecting pads on the top surface. The IPMs cover the corresponding connecting pads in one-on-one alignment where each IPM consists of a photo-sensitive adhesive layer on the corresponding connecting pad and a pick-and-place body pervious to light formed on the photo-sensitive adhesive layer. After the photo-sensitive adhesive layers are irradiated by light penetrating through the pick-and-place bodies, the pick-and-place bodies can be pulled out by a pick-and-place process to expose the connecting pads from an encapsulant. The issues of solder bridging and package warpage can easily be solved in conventional MPS-C2 packages.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a substrate; mounting an interposer having a top interposer surface over the substrate; attaching an interposer pad extension to the top interposer surface, the interposer pad extension having an extension contact surface and a lower contact surface, the surface area of the extension contact surface being smaller than the surface area of the lower contact surface; and forming a package encapsulation on the substrate, the interposer, and the interposer pad extension, the package encapsulation having a recess exposing the top interposer surface, the interposer pad extension embedded only in the package encapsulation.

Abstract: The integrated circuit packaging techniques of the disclosed embodiments utilize a thermally conductive heat sink to partially enclose an integrated circuit. The heat sink is separated from the integrated circuit by a substrate that is conformally positioned into a recess in the heat sink, enabling the heat sink to transfer thermal energy from the integrated circuit.

Abstract: A semiconductor device has a first insulating layer formed over a carrier. A first conductive layer is formed over the first insulating layer. A second insulating layer is formed over the first conductive layer. Vias are formed through the second insulating layer. A second conductive layer is formed over the second insulating layer and extends into the vias. A semiconductor die is mounted to the second conductive layer. A bond wire is formed between a contact pad on the semiconductor die and the second conductive layer. The second conductive layer extends to a mounting site of the semiconductor die to minimize the bond wire span. An encapsulant is deposited over the semiconductor die. A portion of the first insulating layer is removed to expose the second conductive layer. A portion of the first conductive layer is removed to electrically isolate remaining portions of the first conductive layer.

Abstract: A semiconductor package includes a first semiconductor chip including a target circuit surface and a side surface, a first sealing insulating layer including a first surface positioned toward the target circuit surface and a second surface positioned opposite to the first surface, the first sealing insulating layer sealing the target circuit surface and the side surface, a wiring layer formed on the first surface of the first sealing insulating layer, an insulating layer formed on the wiring layer, a second semiconductor chip mounted on the second surface of the first sealing insulating layer, and a second sealing insulating layer formed on the second surface and sealing the second semiconductor chip.

Abstract: The chip module includes a semiconductor chip having a first contact element on a first main face and a second contact element on a second main face. The semiconductor chip is arranged on a corner in such a way that the first main face of the semiconductor chip faces the carrier. One or more electrical connectors are connected to the carrier and include end faces located in a plane above a plane of the second main face of the semiconductor chip.

Abstract: A semiconductor package with improved height uniformity of solder cap bumps therein is disclosed. In one embodiment, the semiconductor package includes a semiconductor substrate comprising a plurality of pads spacedly disposed on a top surface of the substrate, and a passivation layer formed on top of the pads, wherein a plurality of pad openings are created to expose at least a portion of the pads; a plurality of solder cap bumps formed at the pad openings of the passivation layer; and a carrier substrate having a plurality of bond pads electrically connected to the solder caps of the solder cap bumps on the semiconductor substrate. The solder cap bump includes a solder cap on top of a conductive pillar, and a patternable layer can be coated and patterned on a top surface of the conductive pillar to define an area for the solder ball to be deposited. The deposited solder ball can be reflowed to form the solder cap.

Abstract: A semiconductor package includes a first semiconductor chip including a target circuit surface and a side surface, a first sealing insulating layer including a first surface positioned toward the target circuit surface and configured to seal the target circuit surface and the side surface, at least one wiring layer formed on the first surface of the first sealing insulating layer, at least one insulating layer formed on the at least one wiring layer, a second semiconductor chip mounted on the at least one insulating layer, and a second sealing insulating layer formed on the at least one insulating layer and configured to seal the second semiconductor chip.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a substrate; mounting a top integrated circuit on a first side of the substrate; mounting a bottom integrated circuit on a second side of the substrate; forming a top encapsulation over the top integrated circuit and a bottom encapsulation over the bottom integrated circuit simultaneously; and forming a bottom via through the bottom encapsulation to the substrate.

Abstract: A support substrate includes a first surface and a second surface located above the level of the first surface. Chips are mounted on the first surface. A first insulating film is disposed over each chip. First conductive plugs are connected to the chip extending through each first insulating film. Filler material made of resin filling a space between chips. Wirings are disposed over the first insulating film and the filler material for interconnecting different chips. The second surface, an upper surface of the first insulating film and an upper surface of the filler material are located at the same level.

Abstract: A method for making a structure including at least the steps of: making at least one first portion of at least one getter material against a first substrate or a second substrate, making at least one second portion of at least one getter material against the second substrate when the first portion of getter material is placed against the first substrate, or against the first substrate when the first portion of getter material is placed against the second substrate, and attaching the second substrate to the first substrate by thermocompression of a first part of the first portion of getter material against at least one part of the second portion of getter material, forming at least one cavity delimited by the first substrate and the second substrate, a second part of the first portion of getter material being placed in the cavity.

Abstract: Packaging methods and structures for semiconductor devices that utilize a novel die attach film are disclosed. In one embodiment, a method of packaging a semiconductor device includes providing a carrier wafer and forming a die attach film (DAF) that includes a polymer over the carrier wafer. A plurality of dies is attached to the DAF, and the plurality of dies is packaged. At least the carrier wafer is removed from the packaged dies, and the packaged dies are singulated.

Abstract: To provide a technology capable of preventing the deterioration of the reliability of semiconductor devices caused by the gasification of a part of components of the material constituting a wiring substrate. A wiring layer constituting a circuit pattern is formed over each of the front and rear surfaces of a glass epoxy substrate, and after the formation of a solder resist covering the wiring layer while exposing a part of the wiring layer and prior to a heat treatment (first heat treatment) at 100° C. to 150° C. for dehumidification, a heat treatment (second heat treatment) at 160° C. to 230° C. for gasifying and discharging an organic solvent contained in the material constituting a wiring substrate is performed for the wiring substrate.

Abstract: A transistor structure includes a chip package and two pins, wherein the chip package includes a transistor die and a molding compound encapsulating the transistor die. One of the pins is electrically connected to a first bonding pad and a second bonding pad of the transistor die, and another of the pins is electrically connected to a third bonding pad of the transistor die. The transistor structure may be employed in a snubber circuit to connect an active component or a load in parallel to absorb spikes or noise generated by the active component while the active component is switching at a high frequency. Therefore, the packaging of the transistor structure could simplify the process, reduce size, increase the withstanding voltage, and improve the efficiency and reduce the spike voltage of the power supply of the snubber circuit.