Abstract: An axially-mountable device includes a semiconductor chip comprising lower and upper electrical contacts. A lower die pad is electrically and mechanically connected to the lower electrical contact of the chip. An upper die pad is electrically and mechanically connected to the upper electrical contact of the chip. A first axially extending electrical lead is electrically and mechanically connected to the upper die pad and extends in a first axial direction. A second axially extending electrical lead is electrically and mechanically connected to the lower die pad and extends in a second axial direction that is opposite to the first axial direction. Packaging material encapsulates the semiconductor chip, the upper and lower die pads and a portion of the first and second axially extending leads. The first and second leads extend from the packaging material and are adapted to allow the device to be axially-mounted with another electrical component.

Abstract: A manufacturing method of semiconductor substrate includes following steps: providing a base layer; forming a plurality of traces on the base layer; forming a plurality of studs correspondingly on the traces; forming a molding material layer on the base layer to encapsulate the traces and studs; forming a concave portion on the molding material layer; and, removing the base layer.

Abstract: A metal lead frame strip is provided for use in manufacturing a packaged electrical device. A ½ thickness engagement portion of the lead frame strip is encapsulated together with the electrical device in a block of encapsulating material to physically secure the lead frame strip to the device package. The device package is later physically separated from the lead frame strip without leaving residual metal exposed on the separated device package.

Abstract: In one embodiment, a method for forming a package substrate includes selectively removing portions of a lead frame to form cavities and filling the cavities with a resin layer to define an adhesion pad and a land structure. Top portions of the lead frame are selectively removed to isolate the adhesion pad and the land structure from each other, to expose a top surface of the resin layer, and to form at least one land having a part with a relatively greater size than the size of a respective lower part.

Abstract: A semiconductor encapsulation comprises a lead frame further comprising a chip carrier and a plurality of pins in adjacent to the chip carrier. A plurality of grooves opened from an upper surface of the chip carrier partially dividing the chip carrier into a plurality of chip mounting areas. A bottom portion of the grooves is removed for completely isolate each chip mounting area, wherein a width of the bottom portion of the grooves removed is smaller than a width of the grooves. In one embodiment, a groove is located between the chip carrier and the pins with a bottom portion of the groove removed for isolate the pins from the chip carrier, wherein a width of the bottom of the grooves removed is smaller than a width of the grooves.

Abstract: The multi-chip leadless module 200 has integrated circuit (IC) 150, dual n-channel mosfet 110, IC leads 210, 211, 212, gate leads 213, 213, and source leads 217-220 encapsulated in resin 250. The IC 150 and the dual n-channel mosfet 110 are mounted face down on the leads. IC leads 210, 211, 212 are made of planar metal and connect, respectively, to the electrodes TEST, VDD and VM on the IC 150 using a flip chip technique to assemble the leads on copper pillars or copper studs.

Abstract: A semiconductor package comprises a die attach pad and a support member at least partially circumscribing it. Several sets of contact pads are attached to the support member. The support member is able to be etched away thereby electrically isolating the contact pads. A method for making a leadframe and subsequently a semiconductor package comprises partially etching desired features into a copper substrate, and then through etching the substrate to form the support member and several sets of contact pads. Die attach, wirebonding and molding follow. The support member is etched away, electrically isolating the contact pads and leaving a groove in the bottom of the package. The groove is able to be filled with epoxy or mold compound.

Abstract: A die attach method for a semiconductor chip with a back metal layer located at the back surface of the semiconductor chip comprises the steps of forming a bonding ball array including a plurality of bonding balls with a same height on a die attach area at a top surface of a die paddle; depositing a die attach material in the bonding ball array area with a thickness of the die attach material equal or slightly larger than the height of the bonding ball; attaching the semiconductor chip to the die attach area at the top surface of the die paddle by the die attach material, wherein the bonding ball array controls the bond line thickness of the die attach material between the back metal layer and the top surface of the die paddle and prevents the semiconductor chip from rotating on the die attach material when it is melted.

Abstract: A semiconductor package with connecting plate for internal connection comprise: a plurality of chips each having a plurality of contact areas on a top surface; one or more connecting plates having a plurality of electrically isolated connecting plate portions each connecting a contact area of the semiconductor chips. The method of making the semiconductor package includes the steps of connecting one or more connecting plates to a plurality of semiconductor chips, applying a molding material to encapsulate the chips and the connecting plates, separating a plurality of connecting plate portions of the connecting plates by shallow cutting through or by grinding.

Abstract: Each stitch part of a plurality of leads of a package has a first region having the most outer surface on which Ag plating is applied and a second region having the most outer surface on which Ni plating is applied. Further, the second region is arranged on a die pad side, and the first region is arranged on a periphery side of a sealer. Therefore, in each stitch part, types of plating applied on the most outer surfaces of the first region and the second region can be differentiated from each other, a thick Al wire can be connected to the second region of the second lead, and a thin Au wire can be connected to the first region of the first lead. As a result, usage of only Au plating can be avoided, so that the cost of the package is reduced.

Abstract: A method of fabricating a semiconductor package is provided, including providing an interposer having a plurality of conductive elements, disposing the interposer on a carrier having a plurality of recessed portions for the conductive elements to be received therein such that the interposer is coupled to the carrier, attaching the semiconductor element to the interposer, and removing the carrier. Coupling the interposer to the carrier prevents the conductive elements from displacement under pressure. Therefore, the conductive elements will not be in poor or no electrical contact with the interposer.

Abstract: A lead frame strip includes an array of sites arranged in at least one row connected to two exterior side rails which traverse the lead frame strip on two opposite sides. Each of the sites is further connected to the two exterior side rails by subrails which extend between the two exterior side rails. Interior side rails extend between the subrails having a length dimension oriented along a first direction. The interior side rails include at least one punch degating aperture having an aperture length oriented along the first direction, wherein a total of the aperture length along the interior side rails is greater than or equal to the die pad length.

Abstract: Substrates and packages for LED-based light devices can significantly improve thermal performance and provide separate electrical and thermal paths through the substrate. One substrate includes multiple electrically insulating base layers. On a top one of these layers are disposed top-side electrical contacts, including light device pads to accommodate a plurality of light devices. External electrical contacts are disposed on an exterior surface of the substrate. Electrical paths connect the top-side electrical contacts to the external electrical contacts. At least portions of some of the electrical paths are disposed between the electrically insulating base layers. The electrical paths can be arranged such that different subsets of the light device pads are addressable independently of each other. A heat dissipation plate can be formed on the bottom surface of a bottom one of the base layers.

Abstract: A semiconductor device comprises an aluminum alloy lead-frame with a passivation layer covering an exposed portion of the aluminum alloy lead-frame. Since aluminum alloy is a low-cost material, and its hardness and flexibility are suitable for deformation process, such as punching, bending, molding and the like, aluminum alloy lead frame is suitable for mass production; furthermore, since its weight is much lower than copper or iron-nickel material, aluminum alloy lead frame is very convenient for the production of semiconductor devices.

Abstract: A method of forming a packaged semiconductor device includes loading an array of package sites in position for saw singulation, saw singulating the array of package sites, and performing a non-electrolytic plating operation on exposed lead tips of individual packages from the array of package sites as the array of package sites is saw singulated.

Abstract: Disclosed herein is a power module package including: a base substrate; a metal layer including a circuit pattern and a connection pad formed on the base substrate; a semiconductor device including a plurality of electrodes mounted on the circuit pattern of the metal layer; and a plurality of lead frames formed on the connection pad of the metal layer and respectively connected to the plurality of electrodes of the semiconductor device.

Abstract: A lead finger of a lead frame has a number of channels or grooves in a portion of its top surface that provide a locking mechanism for securing a bond wire to the lead finger. The bond wire may be attached to the lead finger by stitch bonding.

Abstract: Mechanisms for identifying orientation of a sawed die are provided. By making metal pattern in the corner stress relief region in one corner of the die different from the other corners, users can easily identify the orientation of the die.

Abstract: A method of packaging a power semiconductor die includes providing a first lead frame of a dual gauge lead frame. The first lead frame includes a thick die pad. A tape is attached to a first side of the thick die pad and the power die is attached to a second side of the thick die pad. A second lead frame of the dual gauge lead frame is provided. The second lead frame has thin lead fingers. One end of the lead fingers is attached to an active surface of the power die such that the lead fingers are electrically connected to bonding pads of the power die. A molding compound is then dispensed onto a top surface of the dual gauge lead frame such that the molding compound covers the power die and the lead fingers.

Abstract: An integrated circuit package system includes a first integrated circuit die having die pads only adjacent a single edge of the first integrated circuit die, forming first bonding lands adjacent the single edge, connecting the die pads and the first bonding lands, and encapsulating the die pads and a portion of the first bonding lands to form a first package.

Abstract: An electronic device is disclosed. In one embodiment, the electronic device includes a substrate, a plurality of conducting lines formed on a first conducting material that is disposed on the substrate, and a layer of a second conducting material disposed on the plurality of conducting lines. The conducting lines include a top face and a side face. The layer of the second conducting material includes a first thickness disposed on each of the top faces and a second thickness disposed on each of the side faces. To this end, the first thickness is greater than the second thickness.

Abstract: A dual-leadframe multi-chip package comprises a first leadframe with a first die pad, and a second leadframe with a second die pad; a first chip mounted on the first die pad functioning as a high-side MOSFET and second chip mounted on the second die pad functioning as a low-side MOSFET. The package may further comprises a bypass capacity configured as a third chip mounted on the first die pad or integrated with the first chip. The package may further comprise a three-dimensional connecting plate formed as an integrated structure as the second die pad for electrically connecting a top contact area of the first chip to a bottom contact area of the second chip. A top connecting plate connects a top contact area of the second chip and a top contact area of the third chip to an outer pin of the first leadframe.

Abstract: In one implementation, a semiconductor package including conductive carrier coupled power switches includes a first vertical FET in a first active die having a first source and a first gate on a source side of the first active die and a first drain on a drain side of the first active die. The semiconductor package also includes a second vertical FET in a second active die having a second source and a second gate on a source side of the second active die and a second drain on a drain side of the second active die. The semiconductor package includes a conductive carrier attached to the source side of the first active die and to the drain side of the second active die, the conductive carrier coupling the first source to the second drain.

Abstract: A pressed-contact type semiconductor device includes a power semiconductor element, on an upper surface of which at least a first electrode is formed and on a lower surface of which at least a second electrode is formed, lead frames which face the first electrode and the second electrode of the power semiconductor element respectively, and a clip which applies a pressure to the lead frames while the power semiconductor element is sandwiched by the lead frames, wherein a metallic porous plating part is formed on a surface which faces the first electrode or the second electrode, the surface being a surface of at least one of the lead frames.

Abstract: A manufacturing method of a lead frame substrate includes: applying a photosensitive resist or a dry film to first and second surfaces of a metal plate; pattern-exposing the photosensitive resist or the dry film, and then developing the first surface and the second surface to form on the first surface a first resist pattern for forming a connection post and to form on the second surface a second resist pattern for forming a wiring pattern; etching the first surface partway down the metal plate to form the connection post; filling the first surface with a pre-molding resin to a thickness with which the etched surface is buried; removing the pre-molding resin uniformly in a thickness direction of the pre-molding resin until a bottom surface of the connection post is exposed; and etching the second surface to form a wiring pattern.

Abstract: An electronic component and method of making an electronic component is disclosed. In one embodiment, the electronic component includes a frame having a base layer, a first layer, a second layer including palladium placed on the first layer, and a third layer including gold placed on the second layer. A semiconductor chip is positioned on the frame.

Abstract: A semiconductor package is provided with an Aluminum alloy lead-frame without noble metal plated on the Aluminum base lead-frame. Aluminum alloy material with proper alloy composition and ratio for making an aluminum alloy lead-frame is provided. The aluminum alloy lead-frame is electroplated with a first metal electroplating layer, a second electroplating layer and a third electroplating layer in a sequence. The lead-frame electroplated with the first, second and third metal electroplating layers is then used in the fabrication process of a power semiconductor package including chip connecting, wire bonding, and plastic molding. After the molding process, the area of the lead-frame not covered by the molding compound is electroplated with a fourth metal electroplating layer that is not easy to be oxidized when exposing to air.

Abstract: The invention is directed to firm bonding between semiconductor dies etc bonded to a lead frame and wire-bonding portions of the lead frame by ultrasonic Al wire bonding, and the prevention of shortcircuit between the semiconductor dies etc due to a remaining portion of the outer frame of the lead frame after the outer frame is cut. By extending the wire-bonding portion etc on the lead frame in a wire-bonding direction and connecting the wire-bonding portion etc to the outer frame of the lead frame through a connection lead etc, the ultrasonic vibration force in the ultrasonic Al wire bonding is prevented from dispersing and the Al wire and the wire-bonding portion etc are firmly bonded. The outer frame is cut after a resin sealing process is completed.

Abstract: A semiconductor device includes a source electrode pad formed to a front surface of a semiconductor chip and a metal clip (metal plate) to which a lead is electrically connected. The metal clip includes a chip-connecting portion electrically connected to the source electrode pad via a conductive bonding material, a lead-connecting portion electrically connected to the lead via a conductive bonding material, and an intermediate portion positioned between the chip-connecting portion and the lead-connecting portion. Further, between the intermediate portion and the chip-connecting portion, a step portion, which has shear surfaces disposed to face each other, is provided interposing a joining portion.

Abstract: A semiconductor device has a semiconductor die with an encapsulant deposited over and around the semiconductor die. An opening is formed in a first surface of the encapsulant by etching or LDA. A plurality of bumps is optionally formed over the semiconductor die. A bump is recessed within the opening of the encapsulant. A conductive ink is formed over the first surface of the encapsulant, bump and sidewall of the opening. The conductive ink can be applied by a printing process. An interconnect structure is formed over a second surface of the encapsulant opposite the first surface of the encapsulant. The interconnect structure is electrically connected to the semiconductor die. A semiconductor package is disposed over the first surface of the encapsulant with a plurality of bumps electrically connected to the conductive ink layer. The semiconductor package may contain a memory device.

Abstract: A semiconductor device has a substrate and first conductive layer formed over the substrate. An insulating layer is formed over the first substrate with an opening over the first conductive layer. A second conductive layer is formed within the opening of the insulating layer. A portion of the second conductive layer is removed to expose a horizontal surface and side surfaces of the second conductive layer below a surface of the insulating layer. The second conductive layer has non-linear surfaces to extend a contact area of the second conductive layer. The horizontal surface and side surfaces can be stepped surfaces or formed as a ring. A third conductive layer is formed over the second conductive layer. A plurality of bumps is formed over the horizontal surface and side surfaces of the second conductive layer. A semiconductor die is mounted to the substrate.

Abstract: The semiconductor device includes a tab including a chip supporting surface, and a back surface opposite to the chip supporting surface; a plurality of suspension leads supporting the tab; a plurality of leads arranged between the suspension leads; a semiconductor chip mounted on the chip supporting surface of the tab, the semiconductor chip including a main surface, a plurality of pads formed on the main surface, and a rear surface opposite to the main surface; a seal portion sealing the semiconductor chip such that a part of each of the leads is exposed from the seal portion; and a Pb-free solder formed on the part of each of the leads. A part of the rear surface of the semiconductor chip is contacted with the seal portion.

Abstract: A package substrate may include an insulating substrate, a dummy pad, a signal pad and a plug. The dummy pad may be formed on an upper surface of the insulating substrate. The signal pad may be formed on the upper surface of the insulating substrate. The signal pad may have an upper surface protruded from an upper surface of the dummy pad. The plug may be vertically formed in the insulating substrate. The plug may have an upper end exposed through the upper surface of the insulating substrate and connected with the signal pad and the dummy pad, and a lower end exposed through a lower surface of the insulating substrate. Thus, a signal bump may accurately make contact with the protruded upper surface of the signal pad.

Abstract: A multi-chip package comprises a first chip accommodated in a first housing and a second chip accommodated in a second housing. The first housing and the second housing are arranged in a laterally spaced-apart relationship defining a gap between the first housing and the second housing. An interconnecting structure is configured to span the gap and to electrically couple the first chip and the second chip.

Abstract: An integrated circuit package may be formed using a leadframe having an open space extending therethrough. A shunt is located within the open space such that it is not in contact with any portion of the leadframe. Tape may be applied to the lower surface of the leadframe to support the shunt and hold it in place relative to the leadframe until wirebonding and encapsulation have been completed. Thereafter, the tape may be removed.

Abstract: An integrated circuit package may be formed using a leadframe having an open space extending therethrough. A shunt is located within the open space such that it is not in contact with any portion of the leadframe. Tape may be applied to the lower surface of the leadframe to support the shunt and hold it in place relative to the leadframe until wirebonding and encapsulation have been completed. Thereafter, the tape may be removed.

Abstract: Embodiments described herein relate to a method of manufacturing a packaged circuit having a solder flow-impeding plug on a lead frame. The method includes partially etching an internal surface of a lead frame at dividing lines between future sections of the lead frame as first partial etch forming a trench. A non-conductive material that is adhesive to the lead frame is applied in the trench, such that the non-conductive material extends across the trench to form the solder flow-impeding plug. One or more components are attached to the internal surface of the lead frame and encapsulated. An external surface of the lead frame is etched at the dividing lines to disconnect different sections of lead frame as a second partial etch.

Abstract: A two-sided-access (TSA) eWLB is provided that makes it possible to easily access electrical contact pads disposed on both the front and rear faces of the die(s) of the eWLB package. When fabricating the IC die wafer, metal stamps are formed in the IC die wafer in contact with the rear faces of the IC dies. When the IC dies are subsequently reconstituted in an artificial wafer, portions of the metal stamps are exposed through the mold of the artificial wafer. When the artificial wafer is sawed to singulate the TSA eWLB packages and the packages are mounted on PCBs, any electrical contact pad that is disposed on the rear face of the IC die can be accessed via the respective metal stamp of the IC die.

Abstract: A method of manufacturing a semiconductor package structure is provided. A heat-conductive block is adhered to a portion of a second surface of a conductive substrate via a first adhesive layer. An opening is formed by performing a half-etching process on a first surface of the conductive substrate. The remaining conductive substrate is patterned to form leads and expose a portion of the heat-conductive block. Each lead has a first portion and a second portion. A thickness of the first portion is greater than a thickness of the second portion. A first lower surface of the first portion and a second lower surface of the second portion are coplanar. A chip is disposed on the exposed portion of the heat-conductive block and electrically connected to the second portions of the leads. A first bottom surface of the heat-conductive block and a second bottom surface of a molding compound are coplanar.

Abstract: An electrical connection includes a first wire bonded to adjacent bond pads proximate to an edge of a die and a second wire having one end bonded to a die bond pad distal to the die edge and a second end bonded to a lead finger of a lead frame or a connection pad of a substrate. The second wire crosses and is supported by the first wire. The first wire acts as a brace that prevents the second wire from touching the edge of the die. The first wire also prevents the second wire from excessive lateral movement during encapsulation.

Abstract: A wafer-level packaged semiconductor device is described. In an implementation, the device includes one or more self-assembled resilient leads disposed on an integrated circuit chip. Each of the resilient leads are configured to move from a first position wherein the resilient lead is held adjacent to the chip and a second position wherein the resilient lead is extended away from the chip to interconnect the chip to a printed circuit board. A guard is provided to protect the resilient leads when the resilient leads are in the first position. One or more attachment bumps may also be furnished to facilitate attachment of the device to the printed circuit board.

Abstract: An apparatus including a die including a device side; and a build-up carrier including a body including a plurality of alternating layers of conductive material and dielectric material disposed on the device side of the die, an ultimate conductive layer patterned into a plurality of pads or lands; and a grid array including a plurality of conductive posts disposed on respective ones of the plurality of pads of the ultimate conductive layer of the body, at least one of the posts coupled to at least one of the contact points of the die through at least a portion of the conductive material of the body. A method including forming a body of a build-up carrier including a die, the body of the build-up carrier including an ultimate conductive layer and forming a grid array including a plurality of conductive posts on the ultimate conductive layer of the body.

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 semiconductor device according to an embodiment includes: a first unit device configured to include a semiconductor chip, a backside electrode that is in contact with a backside of the semiconductor chip, and a bonding wire in which one end is connected to the backside electrode; a second unit device configured to have a function different from that of the first unit device; a resin layer configured to fix the first and second unit devices to each other; and a first wiring that is formed on the resin layer on a surface side of the semiconductor chip and connected to the other end of the bonding wire.

Abstract: A semiconductor device comprises an aluminum alloy lead-frame with a passivation layer covering an exposed portion of the aluminum alloy lead-frame. Since aluminum alloy is a low-cost material, and its hardness and flexibility are suitable for deformation process, such as punching, bending, molding and the like, aluminum alloy lead frame is suitable for mass production; furthermore, since its weight is much lower than copper or iron-nickel material, aluminum alloy lead frame is very convenient for the production of semiconductor devices.

Abstract: A method of assembling semiconductor devices includes dispensing a metal paste including metal particles in a solvent onto a bonding area of a plurality of metal terminals of a leadframe. The dispensing provides a varying thickness over the bonding area. The solvent is evaporated to form a sloped metal coating including a first sloped top face and a second sloped top face. The first sloped top face is closer to the die pad compared to the second sloped top face, the second sloped top face increases in coating thickness with decreasing distance to the die pad, and the first sloped top face decreases in coating thickness with decreasing distance to the die pad. A bottom side of semiconductor die including a plurality of top side bond pads is attached to the die pad. Bond wires are connected between the bond pads and the second sloped top faces.

Abstract: A semiconductor device according to the present disclosure includes: a plate (13) having a through hole (15); a metal column (16) fixed to the through hole with an insulating member (17) interposed therebetween, and having a projection projecting from the upper surface of the plate; a semiconductor element (12) fixed to the projection; a lead frame (11) electrically connected to the semiconductor element; and a package (14) covering the semiconductor element, and also covering at least part of each of the plate, the metal column, and the lead frame. The lower surface (13b) of the plate is exposed from the package.

Abstract: A package includes a first plated area, a second plated area, a die attached to the first plated area, and a bond coupling the die to the second plated area. The package further includes a molding encapsulating the die, the bond, and the top surfaces of the first and second plated areas, such that the bottom surfaces of the first and second plated areas are exposed exterior to the package. Additional embodiments include a method of making the package.

Abstract: A pressure sensor package is provided that reduces the occurrence of micro gaps between molding material and metal contacts that can store high-pressure air. The present invention provides this capability by reducing or eliminating interfaces between package molding material and metal contacts. In one embodiment, a control die is electrically coupled to a lead frame and then encapsulated in molding material, using a technique that forms a cavity over a portion of the control die. The cavity exposes contacts on the free surface of the control die that can be electrically coupled to a pressure sensor device using, for example, wire bonding techniques. In another embodiment, a region of a substrate can be encapsulated in molding material, using a technique that forms a cavity over a sub-portion of the substrate that includes contacts. A pressure sensor device can be electrically coupled to the exposed contacts.

Abstract: A semiconductor device has a plurality of electronic components mounted on an insulating substrate formed with a metal layer, and electrically connected to each other or to the metal layer; a positioning wire member having a predetermined diameter and a predetermined length, and bonded to each of the plurality of electronic components or to the metal layer; a lead frame disposed to bridge and electrically connect the plurality of electronic components to each other or between the metal layer and the electronic components; and an opening having a size capable of inserting the wire member therethrough formed to penetrate through the lead frame, to join the lead frame to each of the electronic components or the metal layer at a predetermined position therein. The lead frame is positioned on the insulating substrate by inserting the wire member into the opening.