Abstract: A lateral power semiconductor device has a substrate and an isolation layer formed over the substrate for reducing minority carrier storage in the substrate. A well region is formed over the isolation layer. A source region, drain region, and channel region are formed in the well. A first region is formed on a surface of the lateral power semiconductor device adjacent to the source region. The lateral power semiconductor device has a body diode between the first region and drain region. The isolation layer confines the minority carrier charge from the body diode to a depth of less than 20 ?m from the surface of the lateral power semiconductor device. In one embodiment, the isolation layer is a buried oxide layer and the substrate is an n-type or p-type handle wafer. Alternatively, the isolation layer is an epitaxial layer and the substrate is made with N+ or P+ semiconductor material.

Abstract: A semiconductor device has a conductive via formed around a perimeter of the semiconductor die. First and second conductive layers are formed on opposite sides of the semiconductor die and thermally connected to the conductive via. An insulating layer is formed over the semiconductor die. A portion of the insulating layer is removed to expose the first conductive layer and a thermal dissipation region of semiconductor die. A thermal via is formed through the insulating layer to the first conductive layer. A thermally conductive layer is formed over the thermal dissipation region and thermal via. A thermal conduction path is formed from the thermal dissipation region through the thermally conductive layer, thermal via, first conductive layer, conductive via, and second conductive layer. The thermal conduction path terminates in an external thermal ground point. The thermally conductive layer provides shielding for electromagnetic interference.

Abstract: An embedded semiconductor die package is made by mounting a frame carrier to a temporary carrier with an adhesive. The frame carrier includes die mounting sites each having a lead frame interconnect structure around a cavity. A semiconductor die is disposed in each cavity. An encapsulant is deposited in the cavity over the die. A package interconnect structure is formed over the lead frame interconnect structure and encapsulant. The package interconnect structure and lead frame interconnect structure are electrically connected to the die. The frame carrier is singulated into individual embedded die packages. The semiconductor die can be vertically stacked or placed side-by-side within the cavity. The embedded die packages can be stacked and electrically interconnected through the lead frame interconnect structure. A semiconductor device can be mounted to the embedded die package and electrically connected to the die through the lead frame interconnect structure.

Abstract: A semiconductor die has active circuits formed on its active surface. Contact pads are formed on the active surface of the semiconductor die and coupled to the active circuits. A die extension region is formed around a periphery of the semiconductor die. Through hole vias (THV) are formed in the die extension region. A conductive plane or ring is formed in a center area on the active surface of the semiconductor die. The conductive plane or ring is coupled to a first contact pad for providing a first power supply potential to the active circuits. The conductive plane or ring is electrically connected to a first THV. A conductive ring is formed partially around a perimeter of the conduction plane or ring. The conductive ring is coupled to a second contact pad for providing a second power supply potential to the active circuits. The conductive ring is electrically connected to a second THV.

Abstract: A semiconductor device is fabricated by providing a carrier for supporting the semiconductor device. A first semiconductor die is mounted to the carrier. The first semiconductor die has a contact pad. A first dummy die is mounted to the carrier. The first dummy die has a through-silicon via (TSV). The first semiconductor die and the first dummy die are encapsulated using a wafer molding material. A first interconnect structure is formed over the first semiconductor die and the first dummy die. The first interconnect structure is connected to the contact pad of the first semiconductor die and the TSV of the first dummy die. The carrier is removed and a second interconnect structure is formed over the first semiconductor die and the first dummy die. The second interconnect structure is connected to the TSV of the first dummy die. A semiconductor package is connected to the second interconnect structure.

Abstract: A semiconductor device begins with a wafer having a plurality of bumps formed on a surface of the wafer. An under-film layer is formed over the wafer to completely cover all portions of the bumps with the under-film layer. An adhesive layer is formed over the under-film layer. A support layer is attached over the adhesive layer. A back surface of the wafer undergoes grinding. The support layer provides structural support to the wafer. The support layer is removed to expose the adhesive layer. The adhesive layer is removed to expose the under-film layer. The wafer is singulated into semiconductor die. The semiconductor die is mounted to a substrate by applying force to a back surface of the semiconductor die to press the bumps through under-film layer to contact the substrate while the under-film layer provides an underfill between the semiconductor die and substrate.

Abstract: A computer system models customer response using observable data. The observable data includes transaction, product, price, and promotion. The computer system receives data observable from customer responses. A set of factors including customer traffic within a store, selecting a product, and quantity of selected product is defined as expected values, each in terms of a set of parameters related to customer buying decision. A likelihood function is defined for each of the set of factors. The parameters are solved using the observable data and associated likelihood function. The customer response model is time series of unit sales defined by a product combination of the expected value of customer traffic and the expected value of selecting a product and the expected value of quantity of selected product. A linear relationship is given between different products which includes a constant of proportionality that determines affinity and cannibalization relationships between the products.

Abstract: A semiconductor wafer contains a plurality of die with contact pads disposed on a first surface of each die. Metal vias are formed in trenches in the saw street guides and are surrounded by organic material. Traces connect the contact pads and metal vias. The metal vias can be half-circle vias or full-circle vias. The metal vias are surrounded by organic material. Redistribution layers (RDL) are formed on a second surface of the die opposite the first surface. The RDL and THV provide expanded interconnect flexibility to adjacent die. Repassivation layers are formed between the RDL on the second surface of the die for electrical isolation. The die are stackable and can be placed in a semiconductor package with other die. The RDL provide electrical interconnect to the adjacent die. Bond wires and solder bumps also provide electrical connection to the semiconductor die.

Abstract: A method of laser-marking a semiconductor device involves providing a semiconductor wafer having a plurality of solder bumps formed on contact pads disposed on its active surface. The solder bumps have a diameter of about 250-280 ?m. A backgrinding tape is applied over the solder bumps. The tape is translucent to optical images. A backside of the semiconductor wafer, opposite the active surface, undergoes grinding to reduce wafer thickness. The backside of the semiconductor wafer is laser-marked while the tape remains applied to the solder bumps. The laser-marking system including an optical recognition device, control system, and laser. The optical recognition device reads patterns on the active surface through the tape to control the laser. The tape reduces wafer warpage during laser-marking to about 0.3-0.5 mm. The tape is removed after laser-marking the backside of the semiconductor wafer.

Abstract: A vehicle with lean control has a frame with a steering assembly. An arm assembly is connected to the frame. A pair of first and second shock absorbers is mounted between the frame and the arm assembly on opposite sides of the frame. Each shock absorber has a fluid-filled chamber and floating piston. A load sensor is mounted to the steering assembly for detecting changes of pressure on the steering assembly. The load sensor has a housing, a pressure sensing area disposed in the housing, and provides an electrical signal in response to the pressure sensing area. The load sensor detects pressure applied to the top plate of the housing. An electronic control unit is coupled to the electrical contact of the load sensor. A motor and pump assembly is responsive to the electronic control unit for transferring fluid between the chambers of the first and second shock absorbers.

Abstract: An audio amplifier and speaker system are stacked and magnetically coupled together. The audio amplifier is coupled for receiving an audio signal. A first securing assembly is provided on a bottom surface of the amplifier. The first securing assembly may be a foot formed on the bottom surface of the audio amplifier. The speaker is electrically coupled to the amplifier. A second securing assembly is provided on a top surface of the speaker. The second securing assembly may be a receptacle formed in top surface of the speaker. The foot is inserted into the receptacle. The foot and receptacle are magnetically coupled to attach the amplifier to the speaker. The foot has a first electrical connector, and the receptacle has a second electrical connector mated to the first electrical connector to route the audio signal from the amplifier to the speaker.

Abstract: A chip-scale package houses a monolithic semiconductor die containing first and second lateral metal oxide semiconductor field effect transistors (MOSFETs) formed on a surface of the semiconductor die. The MOSFETs are formed using a lateral double diffused metal oxide semiconductor structure. The first MOSFET has a first conduction terminal coupled to a first package terminal and a second conduction terminal coupled to a second package terminal. The second MOSFET has a first conduction terminal coupled to a control terminal of the first MOSFET, a second conduction terminal coupled to a third package terminal, and a control terminal coupled to a fourth package terminal. A resistor is coupled between the first package terminal and the control terminal of the first MOSFET. A logic level enable signal controls the first MOSFET to enable the second MOSFET to connect a DC voltage from the first package terminal to the second package terminal.

Abstract: A semiconductor device is made by forming a build-up interconnect structure over a substrate. A semiconductor die is mounted to the build-up interconnect structure. The semiconductor die is electrically connected to the build-up interconnect structure. A ground pad is formed on the build-up interconnect structure. An encapsulant is formed over the semiconductor die and build-up interconnect structure. A shielding cage can be formed over the semiconductor die prior to forming the encapsulant. A shielding layer is formed over the encapsulant after forming the build-up interconnect structure to isolate the semiconductor die from inter-device interference. The shielding layer conforms to a geometry of the encapsulant and electrically connects to the ground pad. The shielding layer can be electrically connected to ground through a conductive pillar. The substrate is removed. A backside interconnect structure is formed over the build-up interconnect structure, opposite the semiconductor die.

Abstract: A semiconductor package has a substrate with solder balls. A first semiconductor die is disposed on the substrate. A first double side mold (DSM) internal stackable module (ISM) is in physical contact with the first semiconductor die through a first adhesive, such as a film on wire adhesive. A second DSM ISM is in physical contact with the first DSM ISM through a second adhesive. The arrangement of the first and second DSM ISM reduce headroom requirements for the package and increase device packing density. Each DSM ISM has semiconductor die disposed in cavities. An interposer is disposed above the top DSM ISM. Wire bonds connect the semiconductor die and DSM ISMs to the solder balls. An encapsulant surrounds the first semiconductor die and first DSM ISM with an exposed mold area in the encapsulant above the interposer.

Abstract: A cavity semiconductor package has a pre-molded leadframe construction. The leadframe is formed by molding around a die pad, and plural terminal lands. The leadframe has a hole for an acoustic port, such that the package can be soldered on a back side of a printed circuit board and have air access to a sensor die in the package from a front side of the printed circuit board via the acoustic port. The leadframe may also have a hollow or concave recess that defines an acoustic cavity in conjunction with the sensor die or printed circuit board.

Abstract: A method of manufacturing a semiconductor device includes providing a substrate with an insulation layer disposed on a top surface of the substrate, forming a passive device over the top surface of the substrate, removing the substrate, depositing an insulating polymer film layer over the insulation layer, and depositing a metal layer over the insulating polymer film layer. A solder mask can be formed over the metal layer. A conformal metal layer can then be formed over the solder mask. A notch can be formed in the insulation layer to enhance the connection between the insulating polymer film layer and the insulation layer. Additional semiconductor die can be electrically connected to the passive device. The substrate is removed by removing a first amount of the substrate using a back grind process, and then removing a second amount of the substrate using a wet dry, dry etch, or chemical-mechanical planarization process.

Abstract: A structural panel for a building structure includes first and second stud members each including a neck. Openings and venturi bridges are formed in the neck. At least one flange is attached to the neck. A foam panel extends between the studs. The openings in the neck limit the heat transferred from the stud to the edge of the foam panel. The venturi bridges in the neck also limit the transfer of heat from the neck to the edge of the foam panel.

Abstract: Described is a thermal decomposition treatment system and method of using the thermal decomposition treatment system wherein flammable waste is inputted into a trash burner which is shielded from air or gas and the waste is thermally decomposed and carbonized. The thermal decomposition treatment chamber includes a plurality of heating tubes wherein the flammable waste is inputted into the chambers while hot air is passed through the heating tubes which indirectly heats the flammable waste in an anaerobic environment the resulting gases are purified, recovered and reused.

Abstract: A semiconductor wafer contains a plurality of semiconductor die. The semiconductor wafer is diced to separate the semiconductor die. The semiconductor die are transferred onto a carrier. A die extension region is formed around a periphery of the semiconductor die on the carrier. The carrier is removed. A plurality of through hole vias (THV) is formed in first and second offset rows in the die extension region. A conductive material is deposited in the THVs. A first RDL is formed between contact pads on the semiconductor die and the THVs. A second RDL is formed on a backside of the semiconductor die in electrical contact with the THVs. An under bump metallization is formed in electrical contact with the second RDL. Solder bumps are formed on the under bump metallization. The die extension region is singulated to separate the semiconductor die.

Abstract: A single input pin (48) provides multi-functional features for programming a power supply (10). By connecting the appropriate interface circuit (92, 100, or 112) to the single input pin (48), the power supply (10) is programmed for specific behaviors during power up and toggling of an on/off switch (96, 108). In one mode of operation a light emitting diode (106) in the interface circuit (100) is optically coupled to a microprocessor for signaling the closure of the on/off switch (108), allowing the microprocessor to control the power supply (10) through an opto-coupler (102). In another mode of operation, the single on/off switch (96) controls the power supply (10). In yet another mode of operation, Zener diode (118) in the interface circuit (112) controls the power supply (10) during brown-out and black-out conditions.