Abstract: A method including a printed circuit board electrically coupled to a bottom of a laminate substrate, the laminate substrate having an opening extending through the entire thickness of the laminate substrate, a main die electrically coupled to a top of the laminate substrate, a die stack electrically coupled to a bottom of the main die, the die stack including one or more chips stacked vertically and electrically coupled to one another, the die stack extending into the opening of the laminate substrate, and an interposer positioned between and electrically coupled to a topmost chip and the printed circuit board, the interposer providing an electrical path from the printed circuit board to the topmost chip of the die stack.

Abstract: Fan-out wafer level packaging includes an integrated circuit having a top surface, a bottom surface, a plurality of side surfaces, and a bond pad defined on the top surface. A layer of encapsulant substantially surrounds the side surfaces of the integrated circuit, the layer of encapsulant having a height substantially equal to a height of the integrated circuit. A bump is spaced apart from the integrated circuit, and a redistribution layer electrically couples the bond pad of the integrated circuit to the bump.

Abstract: Embodiments of the subject application provide for a circuit comprising: a lead frame having a first plurality of exposed terminals, the lead frame defining a plane; a laminate substrate in the plane defined by the lead frame, adjacent to the lead frame, and electrically coupled to the lead frame, the laminate substrate having a first surface including a second plurality of exposed terminals and a second surface opposite the first surface; a first one or more dies mounted on the lead frame and electrically coupled to the lead frame; and a second one or more dies mounted on the second surface of the laminate substrate and electrically coupled to the laminate substrate.

Abstract: Method and apparatus for semiconductor device fabrication using a reconstituted wafer is described. In one embodiment, diced semiconductor chips are placed within openings on a frame. A reconstituted wafer is formed by filling a mold compound into the openings. The mold compound is formed around the chips. Finished dies are formed within the reconstituted wafer. The finished dies are separated from the frame.

Abstract: Systems, methods, and other embodiments associated with an etched hybrid die package are described. According to one embodiment, a method includes electrically connecting a semiconductor die to at least one of a plurality of primary leads and at least one feature. The method includes applying an encapsulant material to a lead-frame that includes the plurality of primary leads to form a package body. Portions of the primary leads protrude from the package body and portions of the at least one feature are exposed within the package body. The method includes chemically etching a die pad exposed within the package body to form and electrically isolate the at least one feature from the die pad. Chemically etching includes fully etching the at least one feature from the die pad.

Abstract: A method of forming a focal plane array by: forming a first wafer having sensing material provided on a surface, which is covered by a sacrificial layer, the sensing material being a thermistor material defining at least one pixel; providing supporting legs for the pixel within the sacrificial layer, covering them with a further sacrificial layer and forming first conductive portions in the surface of the sacrificial layer that are in contact with the supporting legs; forming a second wafer having read-out integrated circuit (ROIC), the second wafer being covered by another sacrificial layer, into which is formed second conductive portions in contact with the ROIC; bringing the sacrificial oxide layers of the first wafer and second wafer together such that the first and second conductive portions are aligned and bonding them together such that the sensing material is transferred from the first wafer to the second wafer when a sacrificial bulk layer of the first wafer is removed; and removing the sacrificial l

Abstract: Provided is a chip package structure and a method for forming the chip package. The method includes bonding a plurality of first dies on a carrier, encapsulating in a first molding compound the first dies on the carrier, coupling a plurality of second dies on the first dies using conductive elements, adding an underfill between the second dies and the first dies surrounding the conductive elements, and encapsulating in a second molding compound the second dies and the underfill. The chip package comprises a chip encapsulated in a molding compound, and a larger chip coupled to the first chip via conductive elements, wherein the conductive elements are encapsulated in an underfill between the chip and the larger chip without an interposer, and wherein the larger chip and the underfill are encapsulated in a second molding compound in contact with the molding compound.

Abstract: A single metal layer tape substrate includes a patterned metal layer affixed to a patterned dielectric layer. The dielectric layer is patterned to provide openings exposing lands and bond sites on bond fingers on the land side of the metal layer. The metal layer is patterned to provide circuit traces as appropriate for interconnection with the die (on the die attach side) and with other elements (such as other packages in a multi-package module). Interconnection with a die is made by wire bonding to exposed traces on a die attach side of the metal layer, and bond fingers and lands for access to testing the package are provided on the opposite (land) side of the metal layer.

Abstract: A method for the manufacture of a circuit board containing a component and circuit board containing a component. The invention is based on first manufacturing an intermediate product, which contains the insulator layer of the circuit board and the components, which are set in place inside the insulator layer in such a way that the contact elements of the components face the surface of the intermediate product. After this, the intermediate product is transferred to the circuit-board manufacturing line, on which a suitable number of conductor-pattern layers and, if necessary, insulator layers are manufactured on one or both sides of the intermediate product, in such a way that, when manufacturing the first conductor-pattern layer, the conductor material forms an electrical contact with the contact elements of the components. Alternatively, stages can also be performed on a single manufacturing line.

Abstract: Embodiments of the present disclosure are directed to leadframe packages with wettable sides and methods of manufacturing same. In one embodiment, the leads of the leadframe packages have recesses with a curved profile formed therein. The recesses are plated with a solder wettable layer of conductive material that enables solder to flow along the surface during surface mounting of the package to a board, such as a PCB.

Abstract: An element-connecting board is a lead frame for allowing a light emitting diode element to be connected to one side thereof in a thickness direction. The element-connecting board includes the lead frame which is provided with a plurality of leads disposed with spaces from each other and a first insulating resin portion which is light reflective and fills the spaces.

Abstract: A number of semiconductor chips each include a first main face and a second main face opposite to the first main face. A first encapsulation layer is applied over the second main faces of the semiconductor chips. An electrical wiring layer is applied over the first main faces of the first semiconductor chips. A second encapsulation layer is applied over the electrical wiring layer. The thickness of the first encapsulation layer and the thicknesses of the first semiconductor chips is reduced. The structure can be singulated to obtain a plurality of semiconductor devices.

Abstract: Provided is a method of forming a package-on-package. An encapsulation is formed to cover a wafer using a wafer level molding process. The wafer includes a plurality of semiconductor chips and a plurality of through silicon vias (TSVs) passing through the semiconductor chips. The encapsulant may have openings aligned with the TSVs. The encapsulant and the semiconductor chips are divided to form a plurality of semiconductor packages. Another semiconductor package is stacked on one selected from the semiconductor packages. The other semiconductor package is electrically connected to the TSVs.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a lead frame having a die attach paddle pad and a peripheral lead pad with an inner lead pad between the die attach paddle pad and the peripheral lead pad; forming a component side of the lead frame for exposing an upper portion of a peripheral lead under the peripheral lead pad; forming an encapsulation on the lead frame and the upper portion of the peripheral lead; exposing the peripheral lead pad; depositing a conductive shielding layer on the encapsulation connected to the peripheral lead pad; and forming a mounting side of the lead frame for forming a lower portion of the peripheral lead over a peripheral lead contact pad.

Abstract: A semiconductor device includes a semiconductor chip with bonding pads, the bonding pads being arranged along one side of an element forming surface of the semiconductor chip, a lead frame including first and second internal leads arranged such that tips thereof correspond to some of the bonding pads of the semiconductor chip, and first and second bonding wires by which the first internal leads and the some of the bonding pads are bonded to each other. The semiconductor device further includes a hanging pin section provided on the element non-forming surface of the semiconductor chip, and a sealing member with which the semiconductor chip is sealed including the hanging pin section and a bonding section between the first and second internal leads and the first and second bonding wires.

Abstract: An optical element package includes: an optical element in a form of a chip, and a lens resin having a convex lens surface covering an optical functional surface of the optical element. The convex lens surface is formed as a rough surface having a plurality of minute convex curved surfaces having a vertex in a direction perpendicular to a plane in contact with each part of the convex lens surface.

Abstract: A method of manufacture of an integrated circuit packaging system includes: forming a lead array having an innermost space with an innermost lead having an inner lead profile different around an inner non-horizontal side of the innermost lead; forming a middle lead having a middle lead profile the same around a lead side of the middle lead; placing an integrated circuit in the innermost space adjacent to the innermost lead; and forming a package encapsulation over the integrated circuit, the innermost lead, and the middle lead.

Abstract: A method of molding a semiconductor package includes coating liquid molding resin or disposing solid molding resin on a top surface of a semiconductor chip arranged on a substrate. The solid molding resin may include powdered molding resin or sheet-type molding resin. In a case where liquid molding resin is coated on the top surface of the semiconductor chip, the substrate is mounted between a lower molding and an upper molding, and then melted molding resin is filled in a space between the lower molding and the upper molding. In a case where the solid molding resin is disposed on the top surface of the semiconductor chip, the substrate is mounted on a lower mold and then the solid molding resin is heated and melts into liquid molding resin having flowability. An upper mold is mounted on the lower mold, and melted molding resin is filled in a space between the lower molding and the upper molding.

Abstract: In one embodiment, a semiconductor package includes a clip frame with a first clip having a first support structure, a first lever, and a first contact portion, which is disposed on a front side of the semiconductor package. The first support structure is adjacent an opposite back side of the semiconductor package. The first lever joins the first contact portion and the first support structure. A first die is disposed over the first support structure of the first clip. The first die has a first contact pad on the front side of the semiconductor package. An encapsulant material surrounds the first die and the first clip.

Abstract: A system and method for manufacturing a through silicon via is disclosed. An embodiment comprises forming a through silicon via with a liner protruding from a substrate. A passivation layer is formed over the substrate and the through silicon via, and the passivation layer and liner are recessed from the sidewalls of the through silicon via. Conductive material may then be formed in contact with both the sidewalls and a top surface of the through silicon via.

Abstract: A method of manufacture of an integrated circuit packaging system includes: forming a package paddle group having a first package paddle electrically isolated from a second package paddle; attaching an integrated circuit device on the first package paddle and the second package paddle; forming a standoff terminal adjacent the package paddle group and electrically connected to the integrated circuit device; connecting a paddle connector to the integrated circuit device and the first package paddle and another paddle connector to the integrated circuit device and the second package paddle; and forming an encapsulation over the integrated circuit device, the first package paddle, the second package paddle, and the standoff terminal, the encapsulation exposing a portion of the first package paddle, the second package paddle, and the standoff terminal.

Abstract: Method for bonding of a plurality of chips onto a base wafer which contains chips on the front, the chips being stacked in at least one layer on the back of the base wafer and electrically conductive connections are established between the vertically adjacent chips, with the following steps: a) fixing of the front of the base wafer on a carrier, b) placing at least one layer of chips in defined positions on the back of the base wafer, and c) heat treatment of the chips on the base wafer fixed on the carrier, characterized in that prior to step c) at least partial separation of the chips of the base wafer into separated chip stack sections of the base after takes place.

Abstract: A method, and apparatus resulting from the method, for fabricating a circuit board suitable for mounting electronic components. The method includes drilling a plurality of through-holes in a plurality of dielectric sheets, forming a conductive film on at least one side of each of the plurality of dielectric sheets, and substantially filling each of the plurality of through holes with a conductive material. The conductive material is both electrically and thermally uninterrupted from a first face to a second face of each of the plurality of dielectric sheets. The plurality of dielectric sheets are then sequentially mounted, one atop another, to form the circuit board. The sequential mounting step is performed after the steps of drilling the plurality of through-holes, forming the conductive layer, and substantially filling the plurality of through-holes.

Abstract: Embodiments of the present disclosure are directed to leadframe strips and methods of forming packages that include first separating adjacent leads of a leadframe strip and subsequently singulating components into individual packages. In one embodiment, the adjacent leads are separated by etching through the leads, thereby providing electrical isolation of the adjacent packages. In that regard, if desired, the individual adjacent packages may be electrically tested in leadframe strip form. Subsequently, the individual packages are formed by sawing through the encapsulation material.

Abstract: A semiconductor device has a first semiconductor die and first encapsulant deposited around the first semiconductor die. A first insulating layer is formed over the first semiconductor die and first encapsulant. A first conductive layer is formed over the first insulating layer and electrically connected to a contact pad of the first semiconductor die. A second semiconductor die is mounted to the first insulating layer and first conductive layer. A second encapsulant is deposited around the second semiconductor die. A second insulating layer is formed over the second semiconductor die and second encapsulant. A second conductive layer is formed over the second insulating layer and electrically connected to a contact pad of the second semiconductor die. A plurality of conductive vias is formed continuously through the first and second encapsulants outside a footprint of the first and second semiconductor die electrically connected to the first and second conductive layers.

Abstract: A thermosetting encapsulation adhesive sheet which is used for encapsulating a chip type device (1) having connection electrodes (bumps) (3) and mounted on a wiring circuit board (2). The thermosetting encapsulation adhesive sheet is composed of an epoxy resin composition having a viscosity of 5×104 to 5×106 Pa·s as measured at a temperature of 80 to 120° C. before thermosetting thereof. The thermosetting encapsulation adhesive sheet makes it possible to conveniently encapsulate a hollow device with an improved yield.

Abstract: In accordance with an embodiment of the present invention, a semiconductor module includes a first semiconductor package having a first semiconductor die, which is disposed in a first encapsulant. An opening is disposed in the first encapsulant. A second semiconductor package including a second semiconductor die is disposed in a second encapsulant. The second semiconductor package is disposed at least partially within the opening in the first encapsulant.

Abstract: Solder is simultaneously transferred from a mold to a plurality of 3D assembled modules to provide solder bumps on the modules. The mold includes cavities containing injected molten solder or preformed solder balls. A fixture including resilient pressure pads and vacuum lines extending through the pads applies pressure to the modules when they are positioned on the mold. Following reflow and solder transfer to the modules, the fixture is displaced with respect to the mold. The modules, being attached to the fixture by vacuum pressure through the pads, are displaced from the mold with the fixture.

Abstract: A method of manufacture of an integrated circuit packaging system includes: forming signal contacts; forming a power bar having a power bar terminal, the power bar terminal formed in a staggered position relative to the signal contacts; depositing a terminal pad on the power bar terminal; depositing a contact pad on one of the signal contacts; coupling an integrated circuit die to the power bar terminal and the signal contacts; and forming a package body on the integrated circuit die.

Abstract: A novel die seal design, and method for utilization thereof, controls contact of a mold material with the surfaces of a semiconductor die during application, reducing stresses due to a mismatch of the coefficient of thermal expansion of the mold material and the semiconductor die, thereby reducing cracking of the semiconductor die, resulting in increased yields and lower costs, and permits reuse of elements of a mold tool over a range of die sizes.

Abstract: Methods of fabricating a QFN with wettable flank are described. In an embodiment, a leadframe is used which comprises regions of reduced thickness dam bar which extend across an edge of a kerf width and the QFN are formed using film assisted molding with a shaped mold chase that comprises raised portions which correspond in shape and position to the one or more regions of reduced thickness in the leadframe. The shaped mold chase prevents mold compound from filling recesses under the regions of reduced thickness of leadframe and once diced, each QFN has an edge structure which comprises a small step, into which solder will wet where there are exposed plated leads.

Abstract: Various packages and methods are disclosed. A package according to an embodiment includes a substrate, a chip attached to a surface of the substrate with electrical connectors, a molding compound on the surface of the substrate and around the chip, an adhesive on a surface of the chip that is distal from the surface of the substrate, and a lid on the adhesive. In an embodiment, a region between the molding compound and the lid at a corner of the lid is free from the adhesive. In another embodiment, the lid has a recess in a surface of the lid facing the surface of the molding compound.

Abstract: A semiconductor device includes a first semiconductor chip having a pad electrode formed on an upper surface thereof; a resin section sealing the first semiconductor chip with the upper surface and a side surface of the first semiconductor chip being covered and a lower surface of die first semiconductor chip being exposed; a columnar electrode communicating between the upper surface and the lower surface of the resin section with the upper surface and the lower surface of the columnar electrode being exposed on the resin section and at least a part of the side surface of the columnar electrode being covered; and a bonding wire connecting the pad electrode and the columnar electrode with a part of the bonding wire being embedded in the columnar electrode as one end of the bonding wire being exposed on the lower surface of the columnar electrode and the remaining part of the bonding wire being covered with the resin section, and a method for manufacturing the same.

Abstract: A semiconductor package includes: a chip having an active surface with a plurality of electrode pads and an inactive surface opposite to the active surface; an encapsulant encapsulating the chip and having opposite first and second surfaces, the first surface being flush with the active surface of the chip; and first and second metal layers formed on the second surface of the encapsulant, thereby providing a rigid support to the overall structure to prevent warpage and facilitating heat dissipation of the overall structure.

Abstract: There is reduced the difference in inductance between bonding wires to be coupled to two semiconductor chips stacked one over another. A semiconductor device includes external terminals, lower and upper semiconductor chips, and first and second bonding wires. The lower semiconductor chip has first bonding pads, and the upper semiconductor chip has second bonding pads. The first bonding wire couples the first bonding pad of the lower semiconductor chip and the external terminal, and the second bonding wire couples the second bonding pad of the upper semiconductor chip and the external terminal. The diameter of the second bonding wire is larger than the diameter of the first bonding wire.

Abstract: A microelectronic assembly or package can include first and second support elements and a microelectronic element between inwardly facing surfaces of the support elements. First connectors and second connectors such as solder balls, metal posts, stud bumps, or the like face inwardly from the respective support elements and are aligned with and electrically coupled with one another in columns. The first connectors, the second connectors or both may be partially encapsulated prior to electrically coupling respective pairs of first and second connectors in columns. A method may include arranging extremities of first connectors or second connectors in a temporary layer before forming the partial encapsulation.

Abstract: A method (and apparatus) of assembling a die on an electronic substrate, includes processing an assembly including a substrate and a die, and during the processing, introducing a pre-stress to the assembly during a cure process.

Abstract: A semiconductor device has an interposer frame having a die attach area. A uniform height insulating layer is formed over the interposer frame at corners of the die attach area. The insulating layer can be formed as rectangular or circular pillars at the corners of the die attach area. The insulating layer can also be formed in a central region of the die attach area. A semiconductor die has a plurality of bumps formed over an active surface of the semiconductor die. The bumps can have a non-fusible portion and fusible portion. The semiconductor die is mounted over the insulating layer which provides a uniform standoff distance between the semiconductor die and interposer frame. The bumps of the semiconductor die are bonded to the interposer frame. An encapsulant is deposited over the semiconductor die and interposer frame and between the semiconductor die and interposer frame.

Abstract: A semiconductor device mountable to a substrate is provided. The device includes a semiconductor package having at least one semiconductor die, an electrically conductive attachment region, and a packaging material in which is embedded the semiconductor die and a first portion of the electrically conductive attachment region contacting the die. A metallic shell encloses the embedded semiconductor die and the first portion of the electrically conductive attachment region.

Abstract: A lead carrier provides support for an integrated circuit chip and associated leads during manufacture as packages containing such chips. The lead carrier includes a temporary support member with multiple package sites. Each package site includes a die attach pad surrounded by a plurality of terminal pads. The pads are formed of a sintered electrically conductive material. A chip is mounted upon the die attach pad and wire bonds extend from the chip to the terminal pads. The pads, chip and wire bonds are all encapsulated within a mold compound. The temporary support member can be peeled away and then the individual package sites can be isolated from each other to provide completed packages including multiple surface mount joints for mounting within an electronics system board. Edges of the pads are contoured to cause the pads to engage with the mold compound to securely hold the pads within the package.

Abstract: A method of making a semiconductor packaged device comprises mounting onto a lead frame a bottom of a molded semiconductor chip having a first plastic package body covering a top face of a semiconductor chip, encapsulating the lead frame and the semiconductor chip with a second plastic package body with top surfaces of conductive contact bodies electrically connected to electrodes on the top surface of the semiconductor chip exposed and plating conductive pads on a top surface of the assembly structure to provide external electrical connections to the electrodes through the conductive contact bodies.

Abstract: A method of assembling semiconductor devices includes placing an array of semiconductor dies on a die support. A cap array structure is provided that has a corresponding array of caps supported by a cap frame structure. The cap array structure and the array of semiconductor dies on the die support are aligned, with the caps extending over corresponding semiconductor dies, in a mold chase. The array of semiconductor dies and the array of caps are encapsulated with a molding compound in the mold chase. The encapsulated units of the semiconductor dies with the corresponding caps are removed from the mold chase and singulated. Singulating the encapsulated units may include removing the cap frame structure from the encapsulated units.

Abstract: A semiconductor chip which is mounted on a wiring substrate and which is electrically connected to the wiring substrate is disposed in a sealing apparatus. A sealing resin material made of a thermosetting resin composition is supplied into the sealing apparatus. The sealing resin material contains a solid foreign matter having a cured product of a thermosetting resin, and includes particulates of the thermosetting resin composition pulverized with the solid foreign matter, a granulation powder of the particulates, or a preform of the particulates. The semiconductor chip is resin sealed by using the sealing resin material.

Abstract: Disclosed is a technique in which an excessive resin can be stably cut and removed in a molding step. In a step for separating part of a runner leading to a resin-sealing body from the resin-sealing body, the runner is formed by a first runner and a second runner coupled to the first runner and the resin-sealing body. The runner is separated from a middle of the second runner by supporting, with a first supporting portion, the second runner from the side of the second surface of a lead frame, and by pushing down, with a break pin, the first runner in the direction from the side of the first surface of the lead frame toward the side of the second surface thereof, while the resin-sealing body is in a condition of floating in the air.

Abstract: A multifunction semiconductor package structure includes a substrate unit, a circuit unit, a support unit, a semiconductor unit, a package unit and an electrode unit. The substrate unit includes a substrate body and a first electronic element having a plurality of conductive contact portions. The circuit unit includes a plurality of first conductive layers disposed on the substrate body. The semiconductor unit includes a plurality of second electronic elements. Each second electronic element is electrically connected between two corresponding first conductive layers. The package unit includes a package body disposed on the substrate body to enclose the second electronic elements. The electrode unit includes a plurality of top electrodes, a plurality of bottom electrodes, and a plurality of lateral electrodes electrically connected between the top electrodes and the bottom electrodes.

Abstract: An integrated circuit (“IC”) package including an IC assembly mounted on a leadframe and an encapsulant block covering the IC assembly and portions of the leadframe. The encapsulant block has a molded chamfered outer surface portion and the leadframe has a saw cut outer periphery.

Abstract: An exposed die overmolded flip chip package includes a substrate. A die is flip chip mounted to an upper surface of the substrate. The package further includes a mold cap filling a space between an active surface of the die and the upper surface of the substrate. The mold cap includes a principal surface, sidewalls extending from the upper surface of the substrate to the principal surface, an annular surface coplanar with the inactive surface of the die and extending outward from a peripheral edge of the inactive surface of the die, and protruding surfaces extending between the principal surface and the annular surface. The mold cap does not cover the inactive surface of the die such that heat transfer from the die to the ambient environment is maximized and the package thickness is minimized.

Abstract: A method of manufacturing a hollow surface mount type electronic component has a preparing step, a gluing step and a cutting step. The preparing step includes preparing a baseboard, a clapboard and a cover board, mounting multiple circuit segments and conducting points on two opposite faces of the baseboard at intervals and boring multiple through holes on the clapboard corresponding to the circuit segments. The gluing step includes mounting multiple electronic elements on the baseboard to connected with the circuit segments, gelatinizing glue on the boards to mount the clapboard between the baseboard and the cover board and pressing the boards by a pressing machine. The cutting step includes cutting the boards by a cutting machine to produce multiple single SDM electronic components.

Abstract: A method for manufacturing a package comprises a first step of forming a metal pattern including a frame and a plurality of leads extending inward from the frame, a second step of molding a resin pattern including a first resin portion which holds the plurality of leads from an inner side thereof, and second resin portions which cover bottom surfaces of peripheral portions, adjacent to portions to be removed, in the plurality of leads while exposing bottom surfaces of the portions to be removed in the plurality of leads, so as to hold the plurality of leads from a lower side thereof, and a third step of cutting the plurality of leads into a plurality of first leads and a plurality of second leads by removing the portions to be removed in the plurality of leads while the resin pattern keeps holding the peripheral portions in the plurality of leads.

Abstract: A semiconductor device includes a substrate having a first side and a second side, the second side having a mounting location for at least one semiconductor element, and the first side having a plurality of locations electrically connected to locations on the second side. A plurality of electrically conductive interconnects are provided at the locations, each having a first end attached at the location and a second end spaced from the substrate, and an encapsulant partially encapsulates the plurality of interconnects and has a surface lying in a first plane. The second ends are located on the side of the first plane opposite from the substrate first side, an annular space in the encapsulant surrounds each of the plurality of electrically conductive interconnects, and the annular space has a bottom located between the first plane and the substrate first side. Also a method for making such a semiconductor device.