Abstract: In one exemplary embodiment, a multi-chip connector is formed to have a first conductive strip that is suitable for attaching to a first semiconductor die and a second conductive strip that is attached suitable for attaching to a second semiconductor die.

Abstract: Apparatus and methods are provided for integrally packaging semiconductor IC (integrated circuit) chips with antennas having one or more radiating elements and tuning elements that are formed from package lead wires that are appropriated shaped and arranged to form antenna structures for millimeter wave applications.

Abstract: In accordance with the present invention, there is provided a semiconductor package (e.g., a QFP package) including a uniquely configured leadframe sized and configured to maximize the available number of exposed leads in the semiconductor package. More particularly, the semiconductor package includes a generally planar die pad or die paddle defining multiple peripheral edge segments. In addition, the semiconductor package includes a plurality of leads. Some of these leads include bottom surface portions which, in the completed semiconductor package, are exposed and at least partially circumvent the die pad, with other leads including portions which protrude from respective side surfaces of a package body in the completed semiconductor package. The semiconductor package also includes one or more power bars and/or one or more ground rings which are integral portions of the original leadframe used to fabricate the same.

Abstract: To improve the heat dissipation characteristics of a semiconductor device. The semiconductor device has a die pad, a heat dissipating plate in the form of a frame arranged between the die pad and a plurality of leads so as to surround the die pad, a plurality of members that connect the die pad and the inner edge of the heat dissipating plate, and a suspension lead linked to the outer extension of the heat dissipating plate, wherein a semiconductor chip the outer shape of which is larger than the die pad is mounted over the die pad and the members. The top surface of the die pad and the top surface of the members at the part in opposition to the back surface of the semiconductor chip are bonded to the back surface of the semiconductor chip in their entire surfaces with a silver paste.

Abstract: Methods and apparatus for improved electrical, mechanical and thermal performance of stacked IC packages are described. An IC package comprises a substrate, a first die, a second die, and an interposer with an opening in a first surface of the interposer configured to accommodate the first die. The first IC die is attached a first surface of the substrate. The interposer is mounted on the first surface of the substrate such that the first IC die is placed within the opening in the interposer. The second die is mounted on a second surface of the interposer. Wire bonds couple bond pads on the first surfaces of IC die are coupled to the first surface of the substrate. A mold compound encapsulates the first IC die, the second IC die, the interposer and the wire bonds.

Abstract: A semiconductor device features a semiconductor chip including a MOSFET, a first electrode of the MOSFET disposed on an obverse surface of the chip, a second, control electrode of the MOSFET disposed on the obverse surface, a third electrode of the MOSFET disposed on a second, opposing surface of the chip, first, second, and third conductive members, each having top surface and opposing bottom surface, the first, second, and third conductive members connecting with the first, second, and third electrodes electrically, respectively, a sealing body having top and bottom surfaces and sealing parts of the first, second, and third conductive members, the first conductive member having first, second, and third contiguous portions, the first portion is positioned over the first electrode, the second is positioned between the first and second portions and the third portion is positioned under the obverse surface of the chip.

Abstract: A DFN package includes internally extended package leads. One or more package pads are physically and electrically extended from a first edge of the package to a second, opposite edge of the package. These extended package leads can terminate at the edges of the leadframe. The package pads and the extended package leads where the IC die is attached can have full leadframe thickness. Other extended package lead features can have a reduced leadframe thickness (e.g., about half the leadframe thickness). Leadframe features can be physically and electrically connected to a tie-bar feature which can be an integral part of a leadframe matrix. The tie-bar can stabilize the leadframe features during assembly. The tie-bar can also provide electrical connectivity for post assembly leadframe plating. The tie-bar can be removed during package singulation by sawing or punching techniques to free the leadframe features both physically and electrically.

Abstract: A stacked semiconductor package includes a substrate and a plurality of semiconductor dice stacked on the substrate. Each semiconductor die includes a recess, and a discrete component contained in the recess encapsulated in a die attach polymer. The stacked semiconductor package also includes interconnects electrically connecting the semiconductor dice and discrete components, and an encapsulant encapsulating the dice and the interconnects.

Abstract: A power semiconductor module and a method of manufacture thereof includes lead a frame carrying lead having inner and outer lead portions. The outer lead portions, which are connected by soldering to semiconductor chips simultaneously, eliminate the need for using bonding wires. Since no bonding wire is used for connecting the leads and the semiconductor chips, a sufficient current capacity is obtained. The bonding between an insulating circuit board and the semiconductor chips and the bonding between the semiconductor chips and the leads can be made simultaneously in a single step of reflow-soldering. As a result, the mounting time can be shortened and the power semiconductor module can be manufactured more efficiently.

Abstract: According to an example embodiment, there is method (100) for manufacturing a semiconductor device in an air-cavity package. For a device die having an active surface, a lead frame is provided (5), the lead frame has a top-side surface and an under-side surface, the lead frame has predetermined pad landings on the top-side surface. A laminate material is applied (10) to the top-side surface of the lead frame. In the laminate material, an air-cavity region and contact regions are defined (15, 20, 25, 30, 35). The contact regions provide electrical connections to the predetermined pad landings on the lead frame. With the active circuit surface in an orientation toward the laminate material, the device die is mounted (40, 45). The bond pads of the active surface circuit are connected with ball bonds to the predetermined pad landings on the lead frame. An air-cavity is formed between the active surface of the device die and the top-side surface of the lead frame.

Abstract: A semiconductor package that can fit semiconductor chips of various sizes without having to change the footprint of the carrier package. One aspect of the semiconductor package comprises a leadframe, a semiconductor chip attached to the leadframe, electrical connectors electrically connecting the semiconductor chip to the leadframe, and a sealing material. The leadframe has a plurality of leads, with each one of the plurality of leads having an upper side, a lower exposed side, and a laterally exposed side. The upper side of each one of the plurality of leads defines a generally co-planar surface. Further, after sealing material encapsulates the components of the semiconductor package in a spatial relationship, the lower exposed side and the lateral exposed side of the plurality of leads are exposed to the outside surface of the semiconductor package.

Abstract: A semiconductor device includes a circuit base including an inner lead portion and an outer lead portion. The inner lead portion has a plurality of inner leads. At least part of the inner leads is routed inside a chip mounting area. On both upper and lower surfaces of the circuit base, a first and a second semiconductor chip are mounted. At least part of electrode pads of the first semiconductor chip are electrically connected to electrode pads of the second semiconductor chip via the inner leads.

Abstract: A Chip-On-Lead (COL) type semiconductor package having small chip hidden between leads is revealed. The lower surfaces of the leadframe's leads are attached to a wiring substrate and the leads are horizontally bent to form a die-holding cavity. A smaller chip is disposed on the wiring substrate by passing through the die-holding cavity to be on the same disposing level with the leads. At least a larger chip is disposed on the leads to overlap the smaller chip so that the small chip does not extrude from the leads. The encapsulant encapsulates a plurality of internal parts of the leads, the wiring substrate, and the larger chip. Therefore, the conventional unbalance issue of mold flow above and below the leads leading to cause excessive warpage can be avoided and numbers of stacked larger chips can be increased to have larger memory capacities.

Abstract: An integrated circuit (IC) device includes a lead frame having a first and a second opposing surface and a plurality of lead fingers. A first die including a signal processor is mounted on the first surface of the lead frame while a second die is mounted on the second surface of the lead frame. The second die includes at least one sensor that senses at least one non-electrical parameter and has at least one sensor output that provides a sensing signal for the parameter. The sensor output is coupled to the signal processor for processing the sensing signal.

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: An integrated circuit package system is provided including forming an external interconnect and a tie bar, forming a lead tip and a lead body of the external interconnect, forming a hole in the external interconnect, forming a slot in the tie bar, connecting an integrated circuit die and the external interconnect, and molding the external interconnect and the tie bar with the slot and the hole filled.

Abstract: The semiconductor package includes a dielectric layer, a trace layer, a conductive layer, a die and an underfill layer. The dielectric layer has first side and an opposing dielectric layer second side. Multiple vias extend through the dielectric layer from the dielectric layer first side to the dielectric layer second side. Multiple solder balls are disposed at the dielectric layer second side. Each of the solder balls is electrically coupled to a different one of the vias. The die is electrically coupled to the solder balls. The conductive layer is disposed between the dielectric layer second side and the die. The conductive layer defines a window there through for allowing the solder balls to electrically couple to the vias without contacting the conductive layer, i.e., no physical or electrical contact. The underfill layer is formed between the die and the conductive layer, while the trace layer is formed at the dielectric layer first side.

Abstract: A method is provided for forming a microelectronic package at a wafer level. Such method can include providing a semiconductor wafer having a surface with a pattern of electrical contacts thereon. An interposer component can be provided which has a compliant dielectric layer bonded to a conductive layer. A pattern of holes can be formed through the compliant dielectric layer and the conductive layer which corresponds to the pattern of electrical contacts. The compliant dielectric layer can be contacted with the semiconductor wafer surface so that the pattern of holes is in an aligned position with the pattern of contacts and the compliant dielectric layer and the semiconductor wafer surface then bonded in the aligned position to unite the semiconductor wafer and the interposer component to form a wafer level semiconductor package. The wafer level semiconductor package can be diced to form individual semiconductor chip packages.

Abstract: A semiconductor die package includes: an assembly including a semiconductor die, a clip structure attached to an upper surface of the semiconductor die, and a heat sink attached to an upper surface of the clip structure; and a molding material partially encapsulating the assembly, wherein an upper surface of the heat sink is exposed through the molding material.

Abstract: A chip package structure including a chip, a lead frame, first bonding wires and second bonding wires is provided. The chip has an active surface and chip bonding pads disposed thereon. The lead frame is fixed on the chip and the lead frame includes inner leads, at least one bus bar, an insulating layer and transfer bonding pads. The bus bar is located between the chip bonding pads and the inner leads. The insulating layer is disposed on the bus bar and the transfer bonding pads are disposed thereon. The inner leads and the bus bar are located above the active surface. The chip and the insulating layer are located respectively on two opposite surfaces of the bus bar. The first bonding wires respectively connect the chip bonding pads and the transfer bonding pads. The second bonding wires respectively connect the transfer bonding pads and the inner leads.

Abstract: An integrated circuit package system including forming a leadframe having a lead with a leadfinger support of a predetermined height, and attaching an integrated circuit die with an electrical interconnect at a predetermined collapse height determined by the predetermined height of the leadfinger support.

Abstract: A fabrication method for a BGA or LGA package includes a low-cost metal leadframe with internally extended leads. I/O attach lands can be placed at any location on the metal leadframe, including the center of the package. An I/O attach land can be fabricated at any position upon an extended lead (e.g., near the center of the package). During fabrication of the package, an isolation saw cut to the bottom of the package can be used to electrically disconnect the leadframe circuit from the peripheral extension traces to prevent tampering with the IC die by probing the edge metal traces.

Abstract: An integrated circuit package system provides a leadframe having a short lead finger and a long lead finger, and the long lead finger and the short lead finger reside substantially within the same horizontal plane. A first die is placed in the leadframe. A second die is offset from the first die. The offset second die is attached over the first die and the long lead finger with an adhesive. The first die is electrically connected to the short lead finger. The second die is electrically connected to at least the long lead finger or the short lead finger. At least portions of the leadframe, the first die, and the second die are encapsulated in an encapsulant.

Abstract: A package and a fabricating method thereof are provided. The package includes a lead frame, a chip and a sealant. The lead frame has a notch and a plurality of first notch-side leads, a plurality of first notch-side pads, a plurality of second notch-side leads and a plurality of second notch-side pads. The first notch-side leads extend to a first side of the notch. The first notch-side pads are correspondingly disposed on the first notch-side leads. The second notch-side leads extend to a second side of the notch. The second notch-side pads are correspondingly disposed on the second notch-side leads. The sealant seals up the chip and the lead frame and exposes a lower surface of the lead frame. The notch exposes a portion of the sealant.

Abstract: A semiconductor device includes a lead frame including inner lead portion having inner leads connected to outer leads and relay inner leads not connected to the outer leads. A semiconductor element is mounted on a lower surface of the lead frame. Electrode pads of the semiconductor element are connected to the inner lead portion via metal wire. One end of the relay inner lead is connected to the electrode pad via the metal wire, and the other end is connected to the outer lead via a relay metal wire disposed to step over the inner lead.

Abstract: A semiconductor device features a semiconductor substrate with a MOSFET, an electrode for main current of the MOSFET disposed on a first major surface of the substrate, an electrode for control of the MOSFET disposed on the first major surface, a rear plane electrode of the MOSFET disposed on a second, opposing surface of the substrate, and an external connection terminal electrically connected to the rear plane electrode, the external electrode contains a first part, a second part and a third part, the first part is positioned over the rear plane electrode, the third part is positioned below the second major surface and the third part is connected via the second part to the first part.

Abstract: The present invention enables improvement of bonding reliability of the conductive adhesive interposed between a semiconductor chip and a die pad portion. Provided is a semiconductor device, in which a silicon chip is mounted over the die pad portion integrally formed with a drain lead, has a source pad over the main surface and a drain electrode of a power MOSFET over the back side, and is bonded onto the die pad portion via an Ag paste. In the device, a source lead and the source pad are electrically coupled via an Al ribbon. Over the back surface of the silicon chip, an Ag nanoparticle coated film is formed, while another Ag nanoparticle coated film is formed over the die pad portion and lead (drain lead and source lead).

Abstract: An integrated circuit package system provides a leadframe having a short lead finger, a long lead finger, and a support bar. A first die is placed in the leadframe. An adhesive is attached to the first die, the long lead finger, and the support bar. A second die is offset from the first die. The offset second die is attached to the adhesive. The first die is electrically connected to the short lead finger. The second die is electrically connected to at least the long lead finger or the short lead finger. At least portions of the leadframe, the first die, and the second die are encapsulated in an encapsulant.

Abstract: Semiconductor devices that contain a system in package and methods for making such packages are described. The semiconductor device with a system in package (SIP) contains a first IC die, passive components, and discrete devices that are contained in a lower level of the package. The SIP also contains a second IC die that is vertically separated from the first IC die by an array of metal interposers, thereby isolating the components of the first IC die from the components of the second IC die. Such a configuration provides more functionality within a single semiconductor package while also reducing or eliminating local heating in the package. Other embodiments are also described.

Abstract: An exemplary semiconductor die package is disclosed having one or more semiconductor dice disposed on a first substrate, one or more packaged electrical components disposed on a second substrate that is electrical coupled to the first substrate, and an electrically insulating material disposed over portions of the substrates. The first substrate may hold power-handling devices and may be specially constructed to dissipation heat and to facilitate fast and inexpensive manufacturing. The second substrate may hold packaged components of control circuitry for the power-handling devices, and may be specially constructed to enable fast and inexpensive wiring design and fast and inexpensive component assembly. The first substrate may be used with different designs of the second substrate.

Abstract: A BGA package primarily includes a leadless leadframe with a plurality of leads, a chip disposed on the leads, a die-attaching layer adhering to an active surface of the chip and the top surfaces of the leads, a plurality of bonding wires electrically connecting the chip to the leads, an encapsulant, and a plurality of solder balls. Each lead has a bottom surface including a wire-bonding area and a ball-placement area, moreover, a plurality of lips project from the bottom surfaces of the leads around the ball-placement areas. The encapsulant encapsulates the chip, the bonding wires, the die-attaching layer, and the top surfaces, the bottom surfaces except the ball-placement areas. The solder balls are disposed on the ball-placement areas.

Abstract: A semiconductor device is mounted on a package substrate which has a power supply line and a signal line formed of a normal or predetermined resistance material layer on a dielectric layer. A resistance material layer has a high resistance as compared with the normal resistance material layer and is additionally provided on the surface of the normal resistance material layer of the peripheral face of the signal line closest to the power supply line.

Abstract: A multiple die package and removable storage card is disclosed. An insulator layer is provided and one or more vias are formed within it. The insulator may be provided without vias, and vias formed later. At least one integrated circuit is provided and electrically coupled to at least one lead of a first leadframe overlying one surface of the insulator layer. At least one second integrated circuit is provided and electrically coupled to a second leadframe overlying a second surface of the insulator layer. Electrical connections between the two leadframes and the first and second integrated circuits are made through the insulator, at selected locations, by coupling at least one lead of the first and second leadframes one to another. The leads of the first and second leadframe may be electrically coupled via anisotropically conductive areas of the leadframes.

Abstract: This invention discloses a crystalline substrate based device including a crystalline substrate having formed thereon a microstructure; and at least one packaging layer which is sealed over the microstructure by means of an adhesive and defines therewith at least one gap between the crystalline substrate and the at least one packaging layer. A method of producing a crystalline substrate based device is also disclosed.

Abstract: A trench-type storage device includes a trench in a substrate (100), with bundles of carbon nanotubes (202) lining the trench and a trench conductor (300) filling the trench. A trench dielectric (200) may be formed between the carbon nanotubes and the sidewall of the trench. The bundles of carbon nanotubes form an open cylinder structure lining the trench. The device is formed by providing a carbon nanotube catalyst structure on the substrate and patterning the trench in the substrate; the carbon nanotubes are then grown down into the trench to line the trench with the carbon nanotube bundles, after which the trench is filled with the trench conductor.

Abstract: Semiconductor device assemblies and systems that include at least one semiconductor device assembly include two or more semiconductor devices stacked one over another. Conductive pathways that extend around at least one side of at least one of the semiconductor devices provide electrical communication between conductive elements of the semiconductor devices, and optionally, a substrate. The conductive pathways may include self-supporting conductive leads or conductive traces carried by a substrate. Methods for forming semiconductor device assemblies having more than one semiconductor device include bending or wrapping at least one conductive pathway around a side of at least one semiconductor device and providing electrical communication between semiconductor devices of the assembly through the conductive pathways.

Abstract: A semiconductor package assembly may include a lead frame having a die bonding pad and plurality of leads coupled to the first die bonding pad. A vertical semiconductor device may be bonded to the die bonding pad. The device may have a conductive pad electrically connected to one lead through a first bond wire. An electrically isolated conductive trace may be formed from a layer of conductive material of the first semiconductor device. The conductive trace provides an electrically conductive path between the first bond wire and a second bond wire. The conductive path may either pass underneath a third bond wire thereby avoiding the third bond wire crossing another bond wire, or the conductive path may result in a reduced length for the first and second bond wires that is less than a predetermined maximum length.

Abstract: A flip chip lead frame package includes a die and a lead frame having a die paddle and leads, and has a spacer to maintain a separation between the die and the die paddle. Also, methods for making the package are disclosed.

Abstract: In one exemplary embodiment, a multi-chip connector is formed to have a first conductive strip that is suitable for attaching to a first semiconductor die and a second conductive strip that is attached suitable for attaching to a second semiconductor die.

Abstract: A copper strap for a semiconductor device package having a contact electrically connected to a die electrode, a leg portion electrically connected to a lead frame, a web portion positioned between the contact and the leg portion and connected to the leg portion and a connection region connecting the web portion to the contact. The contact includes a body having a plurality of formations, each of the plurality of formations having a concavity and an opposing convexity positioned to generally face the die electrode.

Abstract: A Quad Flat Non-leaded (QFN) chip package including a patterned conductive layer, a first solder resist layer, a chip, a plurality of bonding wires and a molding compound is provided. The patterned conductive layer has a first surface and a second surface opposite to each other. The first solder resist layer is disposed on the first surface, wherein a part of the first surface is exposed by the first solder resist layer. The chip is disposed on the first solder resist layer, wherein the first solder resist layer is between the patterned conductive layer and the chip. The bonding wires are electrically connected to the chip and the patterned conductive layer exposed by the first solder resist layer. The molding compound encapsulates the pattern conductive layer, the first solder resist layer, the chip and the bonding wires.

Abstract: A semiconductor package includes a semiconductor substrate having integrated circuits formed on a cell region and a peripheral circuit region adjacent to each other. A bond pad-wiring pattern is formed on the semiconductor substrate. A pad-rearrangement pattern is electrically connected to the bond pad-wiring pattern, The pad-rearrangement pattern includes a bond pad disposed over at least a part of the cell region.

Abstract: Semiconductor die packages and methods of making them are disclosed. An exemplary package comprises a leadframe having a source lead and a gate lead, and a semiconductor die coupled to the source and gate leads at a first surface of the leadframe. The source lead has a protruding region at a second surface of the leadframe. A molding material is disposed around the semiconductor die, the gate lead, and the source lead such that a surface of the die and a surface of the protruding region are left exposed by the molding material. An exemplary method comprises obtaining the semiconductor die and leadframe, and forming a molding material around at least a portion of the leadframe and die such that a surface of the protruding region is exposed through the molding material.

Abstract: A semiconductor package includes a substrate having contacts, and a discrete component on the substrate in electrical communication with the contacts. The package also includes a semiconductor die on the substrate in electrical communication with the contacts, and a die attach polymer attaching the die to the substrate. The die includes a recess, and the discrete component is contained in the recess encapsulated in the die attach polymer. A method for fabricating the package includes the steps of: attaching the discrete component to the substrate, placing the die attach polymer on the discrete component and the substrate, pressing the die into the die attach polymer to encapsulate the discrete component in the recess and attach the die to the substrate, and then placing the die in electrical communication with the discrete component. An electronic system includes the semiconductor package mounted to a system substrate.

Abstract: A redistributed lead frame for use in molded plastic semiconductor package (38) is formed from an electrically conductive substrate by a sequential metal removal process. The process includes: (a) patterning a first side of an electrically conductive substrate to form an array of lands separated by channels, (b) disposing a first molding compound (18) within these channels, (c) patterning a second side of the electrically conductive substrate to form an array of chip attach sites (24) and routing circuits (26) electrically interconnecting the array of lands and the array of chip attached sites (24), (d) directly electrically interconnecting input/output pads on the at least one semiconductor device (28) to chip attach site members (24) of the array of chip attach sites (24), and (e) encapsulating the at least one semiconductor device (28), the array of chip attach sites (24) and the routing circuits (26) with a second molding compound (36).

Abstract: One aspect of the invention relates to a semiconductor device including a housing and a semiconductor chip partly embedded in a plastic housing composition. Another aspect relates to a method for producing the same. The plastic housing composition has at least one host component having a softening temperature and an incorporated component having a phase change temperature. In this case, the softening temperature of the host component is greater than the phase change temperature of the incorporated component.

Abstract: A semiconductor device comprises a semiconductor chip having a rear surface provided with an uneven structure having a preselected pattern and comprised of concave and convex portions. The preselected pattern of the uneven structure is tilted so as to be in parallel to a crystal orientation of <110> of the semiconductor chip. An electrode is disposed on the concave and convex portions of the uneven structure.

Abstract: A diode chip is mounted on two bottom metal leads of a surface-mount package through two flexible links. The links are zigzag cantilevers attached to the metallic plates. The cantilevers serve as springs to support the device and to cushion any temperature stress or bending stress so as not to damage the connection between the device and the metallic leads.

Abstract: A semiconductor device package includes a substrate with one or more pads and at least one semiconductor device that has one or more of its electrodes electrically connected to the substrate pads. The package also includes one or more terminals in electrical connection with the substrate pads and that provide for external connection to the device.

Abstract: A semiconductor package that includes a lead frame riveted to pillars electrically connect to an electrode of a semiconductor die.