Abstract: A device, method and system is directed to fast data storage on a block storage device. New data is written to an empty write block. A location of the new data is tracked. Meta data associated with the new data is written. A lookup table may be updated based in part on the meta data. The new data may be read based the lookup table configured to map a logical address to a physical address.

Abstract: A device, method and system is directed to fast data storage on a block storage device. New data is written to an empty write block. A location of the new data is tracked. Meta data associated with the new data is written. A lookup table may be updated based in part on the meta data. The new data may be read based the lookup table configured to map a logical address to a physical address.

Abstract: A semiconductor device has a first insulating layer formed over a substrate. The substrate has a plurality of conductive layers and plurality of second insulating layers formed between the conductive layers. The substrate can be a PCB or interposer. A plurality of openings is formed in the first insulating layer by etching or laser direct ablation. A semiconductor die has a plurality of bumps formed over a surface of the semiconductor die. The pattern of openings coincides with a pattern of the bumps. The die is mounted to the substrate with the bumps disposed within the openings in the first insulating layer. Alternatively, a conductive paste can be disposed within the openings in the first insulating layer. The bumps are reflowed to electrically connect the die to the first substrate. The bumps are substantially contained within the openings of the first insulating layer to reduce bridging between adjacent bumps.

Abstract: A semiconductor device has a substrate with a source region and a drain region formed on the substrate. A silicide layer is disposed over the source region and drain region. A first interconnect layer is formed over the silicide layer and includes a first runner connected to the source region and second runner connected to the drain region. A second interconnect layer is formed over the first interconnect layer and includes a third runner connected to the first runner and a fourth runner connected to the second runner. An under bump metallization (UBM) is formed over and electrically connected to the second interconnect layer. A mask is disposed over the substrate with an opening in the mask aligned over the UBM. A conductive bump material is deposited within the opening in the mask. The mask is removed and the conductive bump material is reflowed to form a bump.

Abstract: A semiconductor device has a semiconductor wafer with a plurality of semiconductor die including a plurality of contact pads. An insulating layer is formed over the semiconductor wafer and contact pads. An under bump metallization (UBM) is formed over and electrically connected to the plurality of contact pads. A mask is disposed over the semiconductor wafer with a plurality of openings aligned over the plurality of contact pads. A conductive bump material is deposited within the plurality of openings in the mask and onto the UBM. The mask is removed. The conductive bump material is reflowed to form a plurality of bumps with a height less than a width. The plurality of semiconductor die is singulated. A singulated semiconductor die is mounted to a substrate with bumps oriented toward the substrate. Encapsulant is deposited over the substrate and around the singulated semiconductor die.

Abstract: A semiconductor device includes a substrate having a first region and a second region. The first region is electrically isolated from the second region. The semiconductor device further includes a lateral field-effect transistor (FET) disposed within the first region. The lateral FET includes a first terminal and a second terminal. The semiconductor device further includes a diode disposed within the second region, the diode including a plurality of anode regions and a plurality of cathode regions. The semiconductor device further includes a first electrical connection between the first terminal of the lateral FET and the anode regions of the diode, and a second electrical connection between the second terminal of the lateral FET and the cathode regions of the diode. The first and second electrical connections are disposed over a surface of the substrate.

Abstract: A semiconductor device has a well region formed within a substrate. A gate structure is formed over a surface of the substrate. A source region is formed within the substrate adjacent to the gate structure. A drain region is formed within the substrate adjacent to the gate structure. A first clamping region and second clamping region below the source region and drain region. A trench is formed through the source region. The trench allows the width of the source region to be reduced to 0.94 to 1.19 micrometers. A plug is formed through the trench. A source tie is formed through the trench over the plug. An interconnect structure is formed over the source region, drain region, and gate structure. The semiconductor device can be used in a power supply to provide a low voltage to electronic equipment such as a portable electronic device and data processing center.

Abstract: A semiconductor device has a well region formed within a substrate. A gate structure is formed over a surface of the substrate. A source region is formed within the substrate adjacent to the gate structure. A drain region is formed within the substrate adjacent to the gate structure. A first clamping region and second clamping region below the source region and drain region. A trench is formed through the source region. The trench allows the width of the source region to be reduced to 0.94 to 1.19 micrometers. A plug is formed through the trench. A source tie is formed through the trench over the plug. An interconnect structure is formed over the source region, drain region, and gate structure. The semiconductor device can be used in a power supply to provide a low voltage to electronic equipment such as a portable electronic device and data processing center.

Abstract: A semiconductor device has a well region formed within a substrate. A gate structure is formed over a surface of the substrate. A source region is formed within the substrate adjacent to the gate structure. A drain region is formed within the substrate adjacent to the gate structure. A first clamping region and second clamping region below the source region and drain region. A trench is formed through the source region. The trench allows the width of the source region to be reduced to 0.94 to 1.19 micrometers. A plug is formed through the trench. A source tie is formed through the trench over the plug. An interconnect structure is formed over the source region, drain region, and gate structure. The semiconductor device can be used in a power supply to provide a low voltage to electronic equipment such as a portable electronic device and data processing center.

Abstract: A semiconductor device includes a substrate having a first region and a second region. The first region is electrically isolated from the second region. The semiconductor device further includes a lateral field-effect transistor (FET) disposed within the first region. The lateral FET includes a first terminal and a second terminal. The semiconductor device further includes a diode disposed within the second region, the diode including a plurality of anode regions and a plurality of cathode regions. The semiconductor device further includes a first electrical connection between the first terminal of the lateral FET and the anode regions of the diode, and a second electrical connection between the second terminal of the lateral FET and the cathode regions of the diode. The first and second electrical connections are disposed over a surface of the substrate.

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 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 power MOSFET is provided on a semiconductor die to withstand radiation exposure. The semiconductor die is mounted on a die flag of a leadframe. The MOSFET includes a substrate and epitaxial layer formed over the substrate. A source region is formed in a surface of the semiconductor die. The source region is coupled to the die flag. A contact pad is formed on the source region. A base region is formed in the surface of the semiconductor die adjacent to the source region. The base region is electrically connected to the contact pad. A drain region is formed in the surface of the semiconductor die. The drain region is coupled to a first wire bond pad on the leadframe. A gate structure is formed over a channel between the source region and drain region. The gate structure is coupled to a second wire bond pad on the leadframe.

Abstract: A monolithic semiconductor device has an insulating layer formed over a first substrate. A second substrate is disposed over the first insulating layer. A power MOSFET with body diode is formed over the second substrate. A Schottky diode is formed over the second substrate in proximity to the MOSFET. An insulation trench is formed within the second substrate between the MOSFET and Schottky diode. The isolation trench surrounds the MOSFET and first Schottky diode. A first electrical connection is formed between a source of the MOSFET and an anode of the Schottky diode. A second electrical connection is formed between a drain of the MOSFET and a cathode of the Schottky diode. The Schottky diode reduces charge build-up within the body diode and reverse recovery time of the first power MOSFET. The power MOSFET and integrated Schottky can be used in power conversion or audio amplifier circuit.

Abstract: A semiconductor device has a buried oxide layer formed over a substrate. An active silicon layer is formed over the buried oxide layer. A drain region is formed in the active silicon layer. An LDD drift region is formed in the active silicon layer adjacent to the drain region. The drift region has a graded doping distribution. A co-implant region is formed in the active silicon. A source region is formed in the co-implant region. A shallow trench insulator is formed along a top surface of the LDD drift region. The shallow trench isolator has a length less than the LDD drift region. The shallow trench insulator terminates under the polysilicon gate and within the LDD drift region. A polysilicon gate is formed above the active silicon layer between the source region and LDD drift region and at least partially overlapping the shallow trench insulator.

Abstract: A bi-directional power switch is formed as a monolithic semiconductor device. The power switch has two MOSFETs formed with separate source contacts to the external package and a common drain. The MOSFETs have first and second channel regions formed over a well region above a substrate. A first source is formed in the first channel. A first metal makes electrical contact to the first source. A first gate region is formed over the first channel. A second source region is formed in the second channel. A second metal makes electrical contact to the second source. A second gate region is formed over the second channel. A common drain region is disposed between the first and second gate regions. A local oxidation on silicon region and field implant are formed over the common drain region. The metal contacts are formed in the same plane as a single metal layer.

Abstract: A semiconductor device includes a substrate. The substrate includes a semiconductor material. An electrically isolated region is formed over the substrate. A metal-oxide-semiconductor field-effect transistor (MOSFET) is formed over the substrate within the electrically isolated region. The electrically isolated region includes a trench formed around the electrically isolated region. An insulative material such as silicon dioxide (SiO2) may be deposited into the trench. A diode is formed over the substrate within the electrically isolated region. In one embodiment, the diode is a Schottky diode. A metal layer may be formed over a surface of the substrate to form an anode of the diode. A first electrical connection is formed between a source of the MOSFET and an anode of the diode. A second electrical connection is formed between a drain of the MOSFET and a cathode of the diode.

Abstract: A system, method and apparatus directed to fast data storage on a block storage device. New data is written to an empty write block. If the new data is compressible, a compressed version of the new is written into the meta data. A location of the new data is tracked. Meta data associated with the new data is written. A lookup table may be updated based in part on the meta data. The new data may be read based the lookup table configured to map a logical address to a physical address. Disk operations may use state data associated with the meta data to determine the empty write block. A write speed-limit may also be determined based on a lifetime period, a number of life cycles and a device-erase-sector-count for the device. A write speed for the device may be slowed based on the determined write speed-limit.

Abstract: A device, method and system is directed to fast data storage on a block storage device. New data is written to an empty write block. A location of the new data is tracked. Meta data associated with the new data is written. A lookup table may be updated based in part on the meta data. The new data may be read based the lookup table configured to map a logical address to a physical address.

Abstract: A bi-directional power switch is formed as a monolithic semiconductor device. The power switch has two MOSFETs formed with separate source contacts to the external package and a common drain. The MOSFETs have first and second channel regions formed over a well region above a substrate. A first source is formed in the first channel. A first metal makes electrical contact to the first source. A first gate region is formed over the first channel. A second source region is formed in the second channel. A second metal makes electrical contact to the second source. A second gate region is formed over the second channel. A common drain region is disposed between the first and second gate regions. A local oxidation on silicon region and field implant are formed over the common drain region. The metal contacts are formed in the same plane as a single metal layer.