Abstract: A method for fabricating a heat spreader is provided. Heat spreaders are formed and surrounded by a frame. The heat spreaders and frame are connected to one another by tie bars, the heat spreaders and tie bars having respective upper surfaces. At least portions of the upper surfaces of the tie bars are thinned to reduce the heights of the tie bars at least on a singulation line thereon. The frame is formed to support the heat spreader upper surfaces in an elevated position with respect thereto.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a base substrate; attaching a base device over the base substrate; attaching a leadframe having a leadframe pillar adjacent the base device over the base substrate; applying a base encapsulant over the base device, the base substrate, and the leadframe; removing a portion of the base encapsulant and a portion of the leadframe providing the leadframe pillar partially exposed; and attaching a base substrate connector to the base substrate directly below the leadframe pillar.

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 leadframe design for a diode or other semiconductor device that reduces stress on the device and provides increased heat dissipation is provided. According to various embodiments, the leadframe has a contoured profile including a recessed area and a raised surface within the recessed area. The surface supports the device such that the edges of the device extend past the surface. Also provided are device assemblies including the novel leadframes. In certain embodiments, the assemblies include one or more leadframes attached via a solder joint to a device. According to various embodiments, the leadframes are attached to the front side of the device, back side of the device or both. In particular embodiments, the device is a bypass diode for one or more solar cells in a solar module.

Abstract: A high-speed I/O trace is part of an I/O package architecture for an integrated circuit package substrate. The integrated circuit package substrate includes an integrated heat spreader footprint on a die-side and the I/O trace to couple with an IC device to be disposed inside the IHS footprint. The I/O trace includes a pin-out terminal outside the IHS footprint to couple to an IC device to be disposed outside the IHS footprint. The high-speed I/O trace can sustain a data flow rate from a processor in a range from 5 gigabits per second (Gb/s) to 40 Gb/s.

Abstract: A semiconductor device which includes a semiconductor chip; an electrically conductive base electrode bonded to the lower surface of the chip by a first bonding member; an electrically conductive lead electrode bonded to the upper surface of the chip by a second bonding member; and a first stress relief member for reducing stress developed in the first bonding member due to the difference in thermal expansion between the chip and the base electrode. Both the base electrode and the first stress relief member are in direct contact with the lower surface of the first bonding member. A protrusion is formed upstanding from the base electrode in direct contact with the first bonding member, and the first stress relief member surrounds a circumferential portion of the protrusion.

Abstract: An example semiconductor package with reduced solder voiding is described, which has a leadframe having an I/O pad and a thermal pad, a fabricated semiconductor die having a bond pad, where the fabricated semiconductor die is attached to a top surface of the thermal pad, and a wire bond connecting the bond pad to the I/O pad, where a bottom surface of the thermal pad has channels.

Abstract: A resin-sealed semiconductor device includes a power element (1), a control element (4), a first lead frame (3) having a first die pad (3A) which holds the power element (1), a second lead frame (5) having a second die pad (5A) which holds the control element (4), and a housing (6) made of a resin material and sealing the power element, the first die pad, the control element, and the second die pad. A lower surface of the second die pad is higher than an upper surface of the first element, and at least part of the first die pad and at least part of the second die pad overlap each other when viewed from the top. One of the first leads and one of the second leads are directly joined together by a joint portion (23) and electrically coupled together in the housing.

Abstract: According to an embodiment of a high power package, the package includes a heat sink containing enough copper to have a thermal conductivity of at least 350 W/mK, an electrically insulating attached to the heat sink with an epoxy and a semiconductor chip attached to the heat sink on the same side as the lead frame with an electrically conductive material having a melting point of 280° C. or greater.

Abstract: A semiconductor device has a substrate, a semiconductor chip mounted on the substrate, an encapsulating body encapsulating the semiconductor chip on the substrate, and a plurality of heat sink plates embedded in the encapsulating body so as to have a surface that is exposed to an exterior of the encapsulating body and positioned on the same plane. The heat sink plates are spaced from each other.

Abstract: A frame includes heat slug pads coupled together in a N×M matrix such that singulation of the heat slug pads consists of one or more parallel passes across the frame. Each heat slug pad has a top exposed surface and a bottom interfacing surface. The bottom interfacing surface typically interfaces with a package. In some embodiments, the top exposed surface is modified. Alternatively, the bottom interfacing surface is modified. Alternatively, both surfaces are modified. A modified top exposed surface can include a pattern to increase the top exposed surface area. A modified bottom interfacing surface can include a pattern to increase the bottom interfacing surface area, provide reference points, or both. Alternatively or in addition to, the modified bottom interfacing surface can be plated to increase the bottom interfacing surface area. A patterned surface can be obtained via a stamping process or an etching process.

Abstract: An apparatus and a method configured to lower thermal stress is disclosed. One embodiment provides a semiconductor chip, a heat sink plate and a layer structure. The layer structure includes at least a diffusion solder layer and a buffer layer. The layer structure is arranged between the semiconductor chip and the heat sink plate. The buffer layer includes a material, which is soft in comparison to a material of the diffusion solder layer, and includes a layer thickness such that thermal stresses in the semiconductor chip remain below a predetermined value during temperature fluctuations within a temperature range.

Abstract: A semiconductor element to be mounted on a circuit carrier includes a semiconductor die and at least one lead frame. In order to reduce the size required for mounting a semiconductor die on a circuit carrier, a semiconductor element includes a semiconductor die and at least one lead frame. The at least one lead frame is directly attached to the semiconductor die at a connection region of the semiconductor die, and the connection region provides an electrical connection to and mechanical support for the semiconductor die.

Abstract: A conventional semiconductor device has a problem that a frame constituting a heat sink is expensive and the heat sink is highly likely to come off a resin package. A semiconductor device of the present invention reduces the frame price because a heat sink is formed by subjecting a frame with a uniform thickness to pressing or something similar. Furthermore, the heat sink is less likely to come off a resin package because step regions of the heat sink are pressed as connection regions to be connected to the other frame in which leads are arranged, and thereby, resin constituting the resin package goes around the step regions and reaches up to back surfaces of the respective step regions. Moreover, a structure which makes the heat sink much less likely to come off is realized because recessed portions are arranged in the step regions of the heat sink.

Abstract: A method and a package for circuit chip package having a bent structure. The circuit chip package includes: a substrate having a first coefficient of thermal expansion (CTE); a circuit chip, having a second CTE, mounted onto the substrate; a metal foil disposed on the circuit chip in thermal contact with the chip; a metal lid having (i) a third CTE that is different from the first CTE and (ii) a bottom edge region, where the metal lid is disposed on the metal foil in thermal contact with the metal foil; and an adhesive layer along the bottom edge of the metal lid, cured at a first temperature, bonding the lid to the substrate, producing an assembly which, at a second temperature, is transformed to a bent circuit chip package.

Abstract: A load driving device includes: an output power device for driving a load; a driving IC for controlling the output power device, wherein the driving IC is electrically coupled with the output power device through a wire or a connection member; and a first electrode substrate. The output power device and the driving IC are mounted on the first electrode substrate. In this case, the output power device is controlled with high speed, and a mounting area of the output power device and the driving IC is reduced.

Abstract: A flexible semiconductor package includes a flexible substrate. A data chip is disposed over the flexible substrate. The data chip includes a data storage unit for storing data and first bonding pads that are electrically connected to the data storage unit. A control chip is disposed over the flexible substrate. The control chip includes a data processing unit for processing the data in the data chip and second bonding pads that are electrically connected to the data processing unit. Wirings are formed in order to electrically connect the first bonding pads to the second bonding pads.

Abstract: A semiconductor apparatus according to aspects of the invention can include a metal base; resin case having a bonding plane facing metal base; a coating groove formed in bonding plane and holding adhesive for bonding resin case to metal base at a predetermined position, with the top plane of the wall that forms coating groove being spaced apart from the plane which contains bonding plane such that an escape space is formed between the metal base and the resin case; the escape space receiving the excess amount of adhesive which has flowed out from the coating groove; and a receiver groove communicating to the escape space and receiving securely the excess amount of adhesive which the escape space has failed to receive. If an excess amount of adhesive too much for the receiver groove to receive is coated, the excess amount of adhesive can be received in a stopper groove.

Abstract: An LED assembly can include a heat sink base, at least one LED die attached to the heat sink base, and a lens. One or more layers of phosphor can be formed upon the lens. A heat sink, such as a finned heat sink, can attach the heat sink base to the lens. Heat from the LED die can flow through the heat sink base to the heat sink, from which the heat can be dissipated. Similarly, heat from phosphors can flow through the lens to the heat sink, from which the heat can be dissipated. By removing heat from the LED die, more current can be used to drive the LED die, thus providing brighter light. By removing heat from the phosphors, desired colors can be more reliably provided.

Abstract: A BGA type semiconductor device includes: a substrate having wirings and electrodes; a semiconductor element disposed on the substrate, having a rectangular plan shape, and a plurality of electrodes disposed along each side of the semiconductor element; a plurality of wires connecting the electrodes on the semiconductor element with the electrodes on the substrate; a heat dissipation member disposed on the substrate, covering the semiconductor element, and having openings formed in areas facing apex portions of the plurality of wires connected to the electrodes formed along each side of the semiconductor element; and a sealing resin member for covering and sealing the semiconductor element and heat dissipation member.

Abstract: A no-lead electronic package including a heat spreader and method of manufacturing the same. This method includes the steps of selecting a matrix or mapped no-lead lead frame with die receiving area and leads for interconnect; positioning an integrated circuit device within the central aperture and electrically interconnecting the integrated circuit device to the leads; positioning a heat spreader in non-contact proximity to the integrated circuit device such that the integrated circuit device is disposed between the leads and the heat spreader; and encapsulating the integrated device and at least a portion of the heat spreader and leads in a molding resin.

Abstract: A method of manufacture of an integrated circuit packaging system includes: forming a lead frame having contact pads and connection leads; coupling a base integrated circuit to the contact pads; coupling a chip interconnect between the base integrated circuit, the connection leads, the contact pads, or a combination thereof; molding a package body on the connection leads, the base integrated circuit, and the chip interconnects, including having the contact pads exposed; and forming a bottom surface on the package body including forming the connection leads to be coplanar with the bottom surface.

Abstract: A semiconductor module includes a semiconductor chip, a semiconductor frame, a circuit board, and a screw. The semiconductor frame has a main surface having a concave portion in which the semiconductor chip is mounted. The semiconductor frame is thermally and electrically connected with the semiconductor chip through a die bonding material. The circuit board has a grounding pattern and is arranged above the main surface of the semiconductor frame. The screw electrically connects the main surface of the semiconductor frame and the outer peripheral portion of the concave portion to the grounding pattern of the circuit board and mechanically connects the semiconductor frame to the circuit board.

Abstract: An integrated circuit package system includes: providing a tie bar and a lead adjacent thereto; connecting an integrated circuit and the lead; mounting a shield over the integrated circuit with the shield connected to the tie bar; and encapsulating the integrated circuit and the shield. An integrated circuit package system also includes: forming a lead and a support structure with substantially the same material as the lead and elevated above the lead; connecting an integrated circuit and the lead; mounting a shield over the integrated circuit with the shield on the support structure; and encapsulating the integrated circuit and the shield.

Abstract: A heat dissipating package structure includes a chip carrier; a semiconductor chip mounted and electrically connected to the chip carrier; an encapsulant formed on the chip carrier and for encapsulating the chip, with a non-active surface of the chip being exposed from the encapsulant; and a heat spreader having a hollow portion and attached to the encapsulant, wherein the chip is received in the hollow portion and the non-active surface of the chip is completely exposed to the hollow portion, such that heat generated by the chip can be directly dissipated out of the package structure. The present invention also provides a method for fabricating the heat dissipating package structure.

Abstract: A power electronic device package comprising a base member, a device layer, multiple leads, and an encapsulant is provided. The base member is thermally conductive for heat dissipation. The device layer comprises one or more power electronic devices mounted on the base member. The power electronic devices are selectively electrically connected to each other and to the base member to form an internal electronic circuit. The leads extend outwardly from the base member and are electrically connected to the internal electronic circuit. The encapsulant encases the internal electronic circuit, a portion of the base member, and a portion of the leads. The power electronic device package is configured as a transfer molded power module with multiple leads and increased power handling capability. In an embodiment, the base member is electrically conductive to operate as an electrical terminal. The base member may also be isolatably connected to the internal electronic circuit.

Abstract: According to an embodiment of the invention, a system, operable to facilitate dissipation of thermal energy, includes a mold compound, a die, a first lead frame, and a second lead frame. The die is disposed within the mold compound, and in operation generates thermal energy. The first lead frame is disposed at least partially within the mold compound and is operable to facilitate transmission of a signal. The second lead frame is disposed at least partially within the compound, at least partially separated from the first lead frame, and is operable to facilitate a dissipation of thermal energy.

Abstract: A semiconductor device mountable to a substrate includes a semiconductor die and an electrically conductive attachment region having a first attachment surface and a second attachment surface. The first attachment surface is arranged for electrical communication with the semiconductor die. A housing at least in part encloses the semiconductor die and the interlayer material. The housing has a recess disposed through the second attachment surface of the electrically conductive attachment region. A dielectric, thermally conductive interlayer material is located in the recess and secured to the housing. A metallic plate is located in the recess and secured to the interlayer material.

Abstract: An integrated circuit package system is provided forming a substrate having an integrated circuit die thereon, thermally connecting a heat slug and a resilient thermal structure to the integrated circuit die, and encapsulating the resilient thermal structure.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a base substrate; attaching a base device over the base substrate; attaching a leadframe having a leadframe pillar adjacent the base device over the base substrate; applying a base encapsulant over the base device, the base substrate, and the leadframe; removing a portion of the base encapsulant and a portion of the leadframe providing the leadframe pillar partially exposed; and attaching a base substrate connector to the base substrate directly below the leadframe pillar.

Abstract: A semiconductor package includes a carrier, a chip, a stiffener, a heat spreader and an active type heat-spreading element. The chip and the stiffener are disposed on the carrier. The heat spreader is disposed on the stiffener and includes a through opening. The active type heat-spreading element is disposed on the chip and located in the through opening.

Abstract: A semiconductor package including a top-surface metal layer for implementing circuit features provides improvements in top-surface interconnect density, more flexible routing and mounting of top surface semiconductor packages, dies and passive components or a conformal shield cap implementation. The metal layer interconnected with an internal substrate of the semiconductor package by blind vias laser-ablated through the encapsulation and filled with metal. The vias extend from the top surface to an internal package substrate or through the encapsulation to form bottom-side terminals. The metal layer may be formed by circuit patterns and/or terminals embedded within the encapsulation conformal to the top surface by laser-ablating channels in the top surface of the encapsulation and filling the channels with metal. A conformal coating may be applied to the top surface of the semiconductor package over the metal layer to prevent solder bridging to circuit patterns of the metal layer.

Abstract: An air cavity package is manufactured by attaching a die to a surface of a copper heat sink, dispensing a bead of epoxy around a periphery of the heat sink surface after the die is attached to the copper heat sink so that the bead of epoxy generally surrounds the die and placing a ceramic window frame on the bead of epoxy. The epoxy is cured to attach a bottom surface of the ceramic window frame to the copper heat sink.

Abstract: A semiconductor package includes a substrate unit, a die electrically connected to first contact pads, and a package body covering a first patterned conductive layer and the die. The substrate unit includes: (1) the first patterned conductive layer; (2) a first dielectric layer exposing a part of the first patterned conductive layer to form the first contact pads; (3) a second patterned conductive layer; (4) a second dielectric layer defining openings extending from the first patterned conductive layer to the second patterned conductive layer, where the second patterned conductive layer includes second contact pads exposed by the second dielectric layer; and (5) conductive posts extending from the first patterned conductive layer to the second contact pads through the openings, each of the conductive posts filling a corresponding one of the openings. At least one of the conductive posts defines a cavity.

Abstract: Semiconductor packages and methods for making and using the same are described. The semiconductor packages contain a leadframe having an array of holes with a layout corresponding to the land pad array of the package, wherein the holes contain a thermally-conductive dielectric material with a via therein containing an electrically conductive material. The electrically conductive materials can extend past the bottom of the leadframe to form the land pad array of the packages. With such a configuration, the leadframe can act as an embedded heat sink in the package and there is no need to mount an additional heat sink to the package for thermal dissipation, allowing a thinner package to be manufactured. With such a configuration, the semiconductor packages have a full land pad array, providing a smaller footprint and a higher I/O capacity. Other embodiments are also described.

Abstract: An interposer and a semiconductor device including the interposer are provided, which can prevent thermal warpage of an insulative substrate thereof. The interposer is provided with a semiconductor chip in a semiconductor device andmay be disposed between the semiconductor chip and a mount board. The interposer includes: a substrate of an insulative resin; an island on one surface of the substrate to be bonded to a rear surface of the chip; a thermal pad on the other surface opposite the one surface opposed to the island with the intervention of the substrate; and a thermal via extending through the substrate from the one surface to the other surface to thermally connect the island to the thermal pad.

Abstract: A semiconductor chip, a method of fabricating the same and a stacked package having the same are disclosed. The semiconductor chip includes a wafer, a semiconductor device disposed on the wafer, an insulating layer covering the semiconductor device and disposed on the wafer, a deep via formed to penetrate the wafer and the insulating layer, and a heat dissipation member spaced at a predetermined interval from the deep via and penetrating at least a portion of the insulating layer for dissipating heat generated by the deep via.

Abstract: A semiconductor power module includes a semiconductor chip thermally interfaced to a ceramic substrate and a leadframe defined by a flexible circuit disposed intermediate the chip and the ceramic substrate. The flexible circuit includes a conductor layer that is selectively encased in an insulated jacket to ensure adequate electrical insulation between the conductor layer and adjacent conductive surfaces. Preferably, the module is constructed for double side cooling by sandwiching the chip between a pair of ceramic substrates and providing intermediate flexible circuit leadframes on both sides of the chip for electrically accessing the chip terminals.

Abstract: A semiconductor package includes a metal plate, a power element, a lead frame having a die pad, a resin sheet having insulation properties, a control circuit that controls the power element, and a mold resin. The power element is mounted on the die pad, and the die pad is mounted on the metal plate via the resin sheet. The resin sheet is expanded including at least a lower surface of the die pad while the lower surface of the resin sheet is smaller than an surface of the metal plate, and the control circuit is arranged in a region on the metal plate, which region is other than the region where the power element is arranged.

Abstract: An electronic package comprising a semiconductor device, a heat spreader layer, and a thermal interface material layer located between the semiconductor device and the heat spreader layer. The thermal interface material layer includes a resin layer having heat conductive particles suspended therein. A portion of the particles are exposed on at least one non-planar surface of the resin layer such that the portion of exposed particles occupies a majority of a total area of a horizontal plane of the non-planar surface.

Abstract: A lead frame includes a lead frame 11 made by a rolled single-layer of copper and has a lead portion and a chip support portion. The thickness of the lead portion is the same as that of the chip support portion. A heat dispensing plate made of Aluminum is connected to the chip portion and has a rough surface which is not connected with the lead frame. The lead frame is applied by Laser Diode To Package or metal-Oxide-Semiconductor Field Effect Transistor has high efficiency of heat dispensing and low manufacturing cost, and is suitable for different types of chips.

Abstract: A method and apparatus for fabrication of microelectronic devices are shown. In an embodiment of the invention, a microelectronic device comprises a die, the die comprising a first side, a second side, and an edge; a first plate, the first plate coupled with the die; and a package, the die being coupled with the package.

Abstract: A mountable integrated circuit package system includes: providing a base; depositing a photoresist on the base; patterning the photoresist with an opening; filling the opening with a metal; depositing a further metal on the metal to form a lead pad; removing the photoresist; attaching a die over the base; bonding wires between the die and the lead pad; encapsulating the die and the lead pad in an encapsulation formed into a lead pad lock adjacent the lead pad; and removing the base.

Abstract: A portion of a frame body is fixed on a surface of a heat-radiating plate, and on frame body, a semiconductor chip is die-bonded. Next, a prescribed electrode of semiconductor chip and corresponding lead terminal and the like are electrically connected by a prescribed wire. Next, the lead frame is set in a metal mold such that the semiconductor chip is covered with resin from above the semiconductor chip. Thermoplastic resin is introduced into the metal mold, and semiconductor chip and the like are sealed. By taking out the resulting body from the metal mold, a semiconductor is formed. Thus, a semiconductor device can be provided with reduced manufacturing cost.

Abstract: An LED-packaging arrangement, comprising: a first connection block with an enclosure groove at the bottom thereof; a second connection block with an enclosure groove at the bottom thereof; a light-emitting chip positioned at the top of the first connection block and via connection wires electrically coupled to the first and second connection blocks; a positioning/packaging body, and a transparent packaging body. Alternatively, a third connection block is provided with an enclosure groove at the bottom thereof. In this case, the electrical connection originally to the first connection block via the connection wire is changed to the third connection block. The first and second connection blocks are enclosed by the lower part of the positioning/packaging body in position such that the bottom surfaces of the first and second connection blocks are exposed. The upper part of the positioning/packaging body encloses the light-emitting chip so as to create a reflection cap.

Abstract: A leadframe including a chip supporting plate, a lead forming plate, and solder points is provided. A notch is formed on an edge of the chip supporting plate. The thickness of the lead forming plate is less than the thickness of the chip supporting plate. The lead forming plate has a main body, inner leads, and a connecting rod. The inner leads and the connecting rod are extended from an edge of the main body. The connecting rod has an end portion fitting the notch. The solder points are located at the boundary between the end portion and the notch for structurally connecting the connecting rod and the chip supporting plate.

Abstract: An embodiment of the present invention is a technique to fabricate a metal interconnect. A first metal trace is printed on a die attached to a substrate or a cavity of a heat spreader in a package to electrically connect the first metal trace to a power contact in the substrate. A device is mounted on the first metal trace. The device receives power from the substrate when the package is powered.

Abstract: A method for fabricating a multichip module package includes providing a first heat sink positioned for releasing heat from the package and providing a second heat sink positioned proximate the first heat sink. The heat sinks are thermally coupled and electrically isolated to and from one another. A first semiconductor device is attached to the first heat sink in thermal and electrical communication therewith and electrically insulated from the second heat sink. A second semiconductor device is attached to the second heat sink in thermal and electrical communication therewith and electrically insulated from the first heat sink.

Abstract: A semiconductor device formed by using semiconductor packages is provided. The semiconductor device includes two semiconductor packages adjacently arranged in opposite directions on an inductive conductor. Terminals of the two semiconductor packages are joined by a third lead. the third lead is arranged substantially in parallel to the inductive conductor. Leads at the joint portions have, for example, a bent structure, and the third lead is arranged to be close to the inductive conductor.

Abstract: A semiconductor device including: an insulating substrate including a ceramic substrate having first and second principal surfaces, a first metallic conductor fixed on the first principal surface, and a second metallic conductor fixed on the second principal surface; a semiconductor element disposed on the first metallic conductor on the first principal surface; and a base plate connected to the second metallic conductor on the second principal surface, and on which the insulating substrate being disposed. The second metallic conductor includes a joint area connected to the second principal surface, and a non-joint area formed around the joint area.