| Patent application number | Description | Published |
|---|
| 20090108346 | HYBRID-MODE LDMOS - An MOS-bipolar hybrid-mode LDMOS device has a main gate input and a control gate input wherein the device operates in an MOS mode when both gate inputs are enabled, and operates in a bipolar mode when the main gate input is enabled and the control gate input is disabled. The device can drive the gate of a power MOSFET to deliver the high current required by the power MOSFET while in the bipolar mode, and provide a fully switching between supply voltage and ground to the gate of the power MOSFET while in the MOS mode. | 04-30-2009 |
| 20090173966 | INTEGRATED LOW LEAKAGE DIODE - An integrated low leakage diode suitable for operation in a power integrated circuit has a structure similar to a lateral power MOSFET, but with the current flowing through the diode in the opposite direction to a conventional power MOSFET. The anode is connected to the gate and the comparable MOSFET source region which has highly doped regions of both conductivity types connected to the channel region to thereby create a lateral bipolar transistor having its base in the channel region. A second lateral bipolar transistor is formed in the cathode region. As a result, substantially all of the diode current flows at the upper surface of the diode thereby minimizing the substrate leakage current. A deep highly doped region in contact with the layers forming the emitter and the base of the vertical parasitic bipolar transistor inhibits the ability of the vertical parasitic transistor to fully turn on. | 07-09-2009 |
| 20090230468 | LDMOS DEVICES WITH IMPROVED ARCHITECTURES - An LDMOS device includes a substrate of a first conductivity type, an epitaxial layer on the substrate, a buried well of a second conductivity type opposite to the first conductivity type in a lower portion of the epitaxial layer, the epitaxial layer being of the first conductivity type below the buried layer. The device further includes a field oxide located between a drain and both a gate on a gate oxide and a source with a saddle shaped vertical doping gradient of the second conductivity type in the epitaxial layer above the buried well such that the dopant concentration in the epitaxial layer above the buried well and below a central portion of the field oxide is lower than the dopant concentration at the edges of the field oxide nearest the drain and nearest the gate. | 09-17-2009 |
| 20090242982 | SELF-ALIGNED COMPLEMENTARY LDMOS - The invention includes a laterally double-diffused metal-oxide semiconductor (LDMOS) having a reduced size, a high breakdown voltage, and a low on-state resistance. This is achieved by providing a thick gate oxide on the drain side of the device, which reduces electric field crowding in the off-state to reduce the breakdown voltage and forms an accumulation layer in the drift region to reduce the device resistance in the on-state. A version of the device includes a low voltage version with a thin gate oxide on the source side of the device and a high voltage version of the device includes a thick gate oxide on the source side. The LDMOS may be configured in an LNDMOS having an N type source or an LPDMOS having a P type source. The source of the device is fully aligned under the oxide spacer adjacent the gate to provide a large SOA and to reduce the device leakage. | 10-01-2009 |
| 20090267110 | INTEGRATED LOW LEAKAGE SCHOTTKY DIODE - An integrated low leakage Schottky diode has a Schottky barrier junction proximate one side of an MOS gate with one end of a drift region on an opposite side of the gate. Below the Schottky metal and the gate oxide is a RESURF structure of an N− layer over a P− layer which also forms the drift region that ends at the diode's cathode in one embodiment of the present invention. The N− and P− layers have an upward concave shape under the gate. The gate electrode and the Schottky metal are connected to the diode's anode. A P− layer lies between the RESURF structure and an NISO region which has an electrical connection to the anode. A P+ layer under the Schottky metal is in contact with the P− layer through a P well. | 10-29-2009 |
| 20090309132 | INTEGRATED LATCH-UP FREE INSULATED GATE BIPOLAR TRANSISTOR - A lateral Insulated Gate Bipolar Transistor (LIGBT) includes a semiconductor substrate and an anode region in the semiconductor substrate. A cathode region of a first conductivity type in the substrate is laterally spaced from the anode region, and a cathode region of a second conductivity type in the substrate is located proximate to and on a side of the cathode region of the first conductivity type opposite from the anode region. A drift region in the semiconductor substrate extends between the anode region and the cathode region of the first conductivity type. An insulated gate is operatively coupled to the cathode region of the first conductivity type and is located on a side of the cathode region of the first conductivity type opposite from the anode region. An insulating spacer overlies the cathode region of the second conductivity type. The lateral dimensions of the insulating spacer and the cathode region of the second conductivity type are substantially equal and substantially smaller than the lateral dimension of the cathode region of the first conductivity type. | 12-17-2009 |
| 20090321845 | SHORT CHANNEL LV, MV, AND HV CMOS DEVICES - Low voltage, middle voltage and high voltage CMOS devices have upper buffer layers of the same conductivity type as the sources and drains that extend under the sources and drains and the gates but not past the middle of the gates, and lower bulk buffer layers of the opposite conductivity type to the upper buffer layers extend from under the upper buffer layers to past the middle of the gates forming an overlap of the two bulk buffer layers under the gates. The upper buffer layers and the lower bulk buffer layers can be implanted for both the NMOS and PMOS FETs using two masking layers. For middle voltage and high voltage devices the upper buffer layers together with the lower bulk buffer layers provide a resurf region. | 12-31-2009 |
| 20100013012 | INTEGRATED COMPLEMENTARY LOW VOLTAGE RF-LDMOS - Complementary RF LDMOS transistors have gate electrodes over split gate oxides. A source spacer of a second conductivity type extends laterally from the source tap of a first conductivity type to approximately the edge of the gate electrode above the thinnest gate oxide. A body of a first conductivity type extends from approximately the bottom center of the source tap to the substrate surface and lies under most of the thin section of the split gate oxide. The source spacer is approximately the length of the gate sidewall oxide and is self aligned with gate electrode. The body is also self aligned with gate electrode. The drain is surrounded by at least one buffer region which is self aligned to the other edge of the gate electrode above the thickest gate oxide and extends to the below the drain and extends laterally under the thickest gate oxide. Both the source tap and drain are self aligned with the gate side wall oxides and are thereby spaced apart laterally from the gate electrode. | 01-21-2010 |
| 20100084686 | ASSYMETRIC HETERO-DOPED HIGH-VOLTAGE MOSFET (AH2MOS) - An asymmetric heterodoped metal oxide (AH | 04-08-2010 |
| 20100193878 | HIGH SPEED, LOW POWER CONSUMPTION, ISOLATED ANALOG CMOS UNIT - A semiconductor device | 08-05-2010 |
| 20100219471 | QUASI-RESURF LDMOS - A semiconductor device can include a drift region, at least a portion of the drift region located laterally between a drain region and a source region. The drift region can include a first layer having a first doping concentration and a second layer having a second higher doping concentration than the first layer. The second layer of the drift region be configured to allow drift current between the source region and the drain region when a depletion region is formed in at least a portion of the first layer between the source region and the drain region. | 09-02-2010 |
| 20100233862 | INTEGRATED LOW LEAKAGE SCHOTTKY DIODE - An integrated low leakage Schottky diode has a Schottky barrier junction proximate one side of an MOS gate with one end of a drift region on an opposite side of the gate. Below the Schottky metal and the gate oxide is a RESURF structure of an N− layer over a P− layer which also forms the drift region that ends at the diode's cathode in one embodiment of the present invention. The N− and P− layers have an upward concave shape under the gate. The gate electrode and the Schottky metal are connected to the diode's anode. A P− layer lies between the RESURF structure and an NISO region which has an electrical connection to the anode. A P+ layer under the Schottky metal is in contact with the P− layer through a P well. | 09-16-2010 |
| 20100267213 | SELF-ALIGNED COMPLEMENTARY LDMOS - The invention includes a laterally double-diffused metal-oxide semiconductor (LDMOS) having a reduced size, a high breakdown voltage, and a low on-state resistance. This is achieved by providing a thick gate oxide on the drain side of the device, which reduces electric field crowding in the off-state to reduce the breakdown voltage and forms an accumulation layer in the drift region to reduce the device resistance in the on-state. A version of the device includes a low voltage version with a thin gate oxide on the source side of the device and a high voltage version of the device includes a thick gate oxide on the source side. The LDMOS may be configured in an LNDMOS having an N type source or an LPDMOS having a P type source. The source of the device is fully aligned under the oxide spacer adjacent the gate to provide a large SOA and to reduce the device leakage. | 10-21-2010 |
| 20100315155 | HIGH SPEED, LOW POWER CONSUMPTION, ISOLATED ANALOG CMOS UNIT - A semiconductor device including: a low threshold PMOS device formed over an N-type region, the source and drain of the low threshold PMOS formed in P-regions surrounded by N-regions; a low threshold NMOS device formed in a P-type region, the source and drain of the low threshold NMOS formed in N-regions surrounded by P-regions; first and second substrate bias generators, each connected to one of the low threshold devices for generating a substrate bias; a voltage source for generating substrate bias during a standby mode to reduce leakage current; wherein a low voltage threshold is established by the source and drain regions of the low threshold devices and their respective surrounding regions of opposite polarity. | 12-16-2010 |
| 20110042717 | INTEGRATED LOW LEAKAGE DIODE - An integrated low leakage diode suitable for operation in a power integrated circuit has a structure similar to a lateral power MOSFET, but with the current flowing through the diode in the opposite direction to a conventional power MOSFET. The anode is connected to the gate and the comparable MOSFET source region which has highly doped regions of both conductivity types connected to the channel region to thereby create a lateral bipolar transistor having its base in the channel region. A second lateral bipolar transistor is formed in the cathode region. As a result, substantially all of the diode current flows at the upper surface of the diode thereby minimizing the substrate leakage current. A deep highly doped region in contact with the layers forming the emitter and the base of the vertical parasitic bipolar transistor inhibits the ability of the vertical parasitic transistor to fully turn on. | 02-24-2011 |
| 20110104861 | INTEGRATED COMPLEMENTARY LOW VOLTAGE RF-LDMOS - Complementary RF LDMOS transistors have gate electrodes over split gate oxides. A source spacer of a second conductivity type extends laterally from the source tap of a first conductivity type to approximately the edge of the gate electrode above the thinnest gate oxide. A body of a first conductivity type extends from approximately the bottom center of the source tap to the substrate surface and lies under most of the thin section of the split gate oxide. The source spacer is approximately the length of the gate sidewall oxide and is self aligned with gate electrode. The body is also self aligned with gate electrode. The drain is surrounded by at least one buffer region which is self aligned to the other edge of the gate electrode above the thickest gate oxide and extends to the below the drain and extends laterally under the thickest gate oxide. Both the source tap and drain are self aligned with the gate side wall oxides and are thereby spaced apart laterally from the gate electrode. | 05-05-2011 |
| 20110127607 | STEPPED-SOURCE LDMOS ARCHITECTURE - A semiconductor device can include a source region near a working top surface of a semiconductor region. The device can also include a gate located above the working top surface and located laterally between the source and a drain region. The source region and the gate can at least partially laterally overlap a body region near the working top surface. The source region can include a first portion having the first conductivity type, a second portion having a second conductivity type, and a third portion having the second conductivity type. The second portion can be located laterally between the first and third portions and can penetrate into the semiconductor region to a greater depth than the third portion but no more than the first portion. The lateral location of the third portion can be determined at least in part using the lateral location of the gate. | 06-02-2011 |
