Abstract: A guard structure for a semiconductor structure is provided. The guard structure includes a first guard ring, a second guard ring and a third guard ring. The first guard ring has a first conductivity type. The second guard ring has a second conductivity type, and surrounds the first guard ring. The third guard ring has the first conductivity type, and surrounds the second guard ring, wherein the first, the second and the third guard rings are grounded. A method of forming a guard layout pattern for a semiconductor layout pattern is also provided.

Abstract: A device includes a p-well region, and a first High-Voltage N-type Well (HVNW) region and a second HVNW region contacting opposite edges of the p-well region. A P-type Buried Layer (PBL) has opposite edges in contact with the first HVNW region and the second HVNW region. An n-type buried well region is underlying the PBL. The p-well region and the n-type buried well region are in contact with a top surface and a bottom surface, respectively, of the PBL. The device further includes a n-well region in a top portion of the p-well region, an n-type source region in the n-well region, a gate stack overlapping a portion of the p-well region and a portion of the second HVNW region, and a channel region under the gate stack. The channel region interconnects the n-well region and the second HVNW region.

Abstract: A communication apparatus with transmitted rate detecting function and the method therefore is provided. The communication apparatus receives an input signal transmitted at a first rate or a second rate from a remote apparatus. The method includes setting the communication apparatus to operate at an initial receiving rate; sampling the input signal by a specific sampling frequency to generate a sample result; estimating the input transmitted rate of the input signal according to the sample result so as to set the receiving rate of the communication apparatus at a working rate; and communicating with the remote apparatus at the working rate. The second rate is higher than the first rate, and the specific sampling frequency is associated with the initial receiving rate.

Abstract: A device includes a buried well region and a first HVW region of the first conductivity, and an insulation region over the first HVW region. A drain region of the first conductivity type is disposed on a first side of the insulation region and in a top surface region of the first HVW region. A first well region and a second well region of a second conductivity type opposite the first conductivity type are on the second side of the insulation region. A second HVW region of the first conductivity type is disposed between the first and the second well regions, wherein the second HVW region is connected to the buried well region. A source region of the first conductivity type is in a top surface region of the second HVW region, wherein the source region, the drain region, and the buried well region form a JFET.

Abstract: A device includes a buried well region and a first HVW region of the first conductivity, and an insulation region over the first HVW region. A drain region of the first conductivity type is disposed on a first side of the insulation region and in a top surface region of the first HVW region. A first well region and a second well region of a second conductivity type opposite the first conductivity type are on the second side of the insulation region. A second HVW region of the first conductivity type is disposed between the first and the second well regions, wherein the second HVW region is connected to the buried well region. A source region of the first conductivity type is in a top surface region of the second HVW region, wherein the source region, the drain region, and the buried well region form a JFET.

Abstract: A high voltage metal-oxide-semiconductor laterally diffused device (HV LDMOS), particularly an insulated gate bipolar junction transistor (IGBT), and a method of making it are provided in this disclosure. The device includes a semiconductor substrate, a gate structure formed on the substrate, a source and a drain formed in the substrate on either side of the gate structure, a first doped well formed in the substrate, and a second doped well formed in the first well. The gate, source, second doped well, a portion of the first well, and a portion of the drain structure are surrounded by a deep trench isolation feature and an implanted oxygen layer in the silicon substrate.

Abstract: Provided is a high voltage semiconductor device. The high voltage semiconductor device includes a transistor having a gate, a source, and a drain. The source and the drain are formed in a doped substrate and are separated by a drift region of the substrate. The gate is formed over the drift region and between the source and the drain. The transistor is configured to handle high voltage conditions that are at least a few hundred volts. The high voltage semiconductor device includes a dielectric structure formed between the source and the drain of the transistor. The dielectric structure protrudes into and out of the substrate. Different parts of the dielectric structure have uneven thicknesses. The high voltage semiconductor device includes a resistor formed over the dielectric structure. The resistor has a plurality of winding segments that are substantially evenly spaced apart.

Abstract: Provided is a high voltage semiconductor device. The high voltage semiconductor device includes a transistor having a gate, a source, and a drain. The source and the drain are formed in a doped substrate and are separated by a drift region of the substrate. The gate is formed over the drift region and between the source and the drain. The transistor is configured to handle high voltage conditions that are at least a few hundred volts. The high voltage semiconductor device includes a dielectric structure formed between the source and the drain of the transistor. The dielectric structure protrudes into and out of the substrate. Different parts of the dielectric structure have uneven thicknesses. The high voltage semiconductor device includes a resistor formed over the dielectric structure. The resistor has a plurality of winding segments that are substantially evenly spaced apart.

Abstract: A device includes a buried well region and a first HVW region of the first conductivity, and an insulation region over the first HVW region. A drain region of the first conductivity type is disposed on a first side of the insulation region and in a top surface region of the first HVW region. A first well region and a second well region of a second conductivity type opposite the first conductivity type are on the second side of the insulation region. A second HVW region of the first conductivity type is disposed between the first and the second well regions, wherein the second HVW region is connected to the buried well region. A source region of the first conductivity type is in a top surface region of the second HVW region, wherein the source region, the drain region, and the buried well region form a JFET.

Abstract: A high voltage metal-oxide-semiconductor laterally diffused device (HV LDMOS), particularly an insulated gate bipolar junction transistor (IGBT), and a method of making it are provided in this disclosure. The device includes a semiconductor substrate, a gate structure formed on the substrate, a source and a drain formed in the substrate on either side of the gate structure, a first doped well formed in the substrate, and a second doped well formed in the first well. The gate, source, second doped well, a portion of the first well, and a portion of the drain structure are surrounded by a deep trench isolation feature and an implanted oxygen layer in the silicon substrate.

Abstract: A high voltage metal-oxide-semiconductor laterally diffused device (HV LDMOS), particularly an insulated gate bipolar junction transistor (IGBT), and a method of making it are provided in this disclosure. The device includes a semiconductor substrate, a gate structure formed on the substrate, a source and a drain formed in the substrate on either side of the gate structure, a first doped well formed in the substrate, and a second doped well formed in the first well. The gate, source, second doped well, a portion of the first well, and a portion of the drain structure are surrounded by a deep trench isolation feature and an implanted oxygen layer in the silicon substrate.

Abstract: An optical interactive panel includes a cladding layer, a first waveguide array, a second waveguide array, a first set of image sensor, and a second set of image sensor. The cladding layer has a first index of refraction. The first waveguide array has first waveguide channels formed on the cladding layer, wherein the first waveguide channels have a second index of refraction less than the first index of refraction, and extending at a first direction. The second waveguide array has second waveguide channels, formed on the cladding layer and extending at a second direction. The first set of image sensor detects a first set of light signals from the first waveguide channels to determine a first-direction location. The second set of image sensor detects a second set of light signals from the second waveguide channels to determine a second-direction location.

Abstract: A communication apparatus with transmitted rate detecting function and the method therefore is provided. The communication apparatus receives an input signal transmitted at a first rate or a second rate from a remote apparatus. The method includes setting the communication apparatus to operate at an initial receiving rate; sampling the input signal by a specific sampling frequency to generate a sample result; estimating the input transmitted rate of the input signal according to the sample result so as to set the receiving rate of the communication apparatus at a working rate; and communicating with the remote apparatus at the working rate. The second rate is higher than the first rate, and the specific sampling frequency is associated with the initial receiving rate.

Abstract: A semiconductor device having integrated MOSFET and Schottky diode includes a substrate having a MOSFET region and a Schottky diode region defined thereon; a plurality of first trenches formed in the MOSFET region; and a plurality of second trenches formed in the Schottky diode region. The first trenches respectively including a first insulating layer formed over the sidewalls and bottom of the first trench and a first conductive layer filling the first trench serve as a trenched gate of the trench MOSFET. The second trenches respectively include a second insulating layer formed over the sidewalls and bottom of the second trench and a second conductive layer filling the second trench. A depth and a width of the second trenches are larger than that of the first trenches; and a thickness of the second insulating layer is larger than that of the first insulating layer.

Abstract: An IGBT with a fast reverse recovery time rectifier includes an N-type drift epitaxial layer, a gate, a gate insulating layer, a P-type doped base region, an N-type doped source region, a P-type doped contact region, and a P-type lightly doped region. The P-type doped base region is disposed in the N-type drift epitaxial layer, and the P-type doped contact region is disposed in the N-type drift epitaxial layer. The P-type lightly doped region is disposed between the P-type contact doped region and the N-type drift epitaxial layer, and is in contact with the N-type drift epitaxial layer.

Abstract: A power semiconductor device with drain voltage protection includes a semiconductor substrate, at least a trench gate transistor device and at least a trench ESD protection device. An upper surface of the semiconductor substrate has a first trench and a second trench. The trench gate transistor device is disposed in the first trench and the semiconductor substrate. The trench ESD protection device is disposed in the second trench, and includes a first doped region, a second doped region and a third doped region. The first doped region and the third doped region are respectively electrically connected to a drain and a gate of the trench gate transistor device.

Abstract: An integrated structure of an IGBT and a diode includes a plurality of doped cathode regions, and a method of forming the same is provided. The doped cathode regions are stacked in a semiconductor substrate, overlapping and contacting with each other. As compared with other doped cathode regions, the higher a doped cathode region is disposed, the larger implantation area the doped cathode region has. The doped cathode regions and the semiconductor substrate have different conductive types, and are applied as a cathode of the diode and a collector of the IGBT. The stacked doped cathode regions can increase the thinness of the cathode, and prevent the wafer from being overly thinned and broken.

Abstract: An overlapping trench gate semiconductor device includes a semiconductor substrate, a plurality of shallow trenches disposed on the semiconductor substrate, a first conductive layer disposed in the shallow trenches, a plurality of deep trenches respectively disposed in each shallow trench, a second conductive layer disposed in the deep trenches, a source metal layer and a gate metal layer. Each of the deep trenches extends into the semiconductor substrate under each shallow trench. The source metal layer is electrically connected to the second conductive layer, and the gate metal layer is electrically connected to the first conductive layer.

Abstract: A power semiconductor device includes a backside metal layer, a substrate formed on the backside metal layer, a semiconductor layer formed on the substrate, and a frontside metal layer. The semiconductor layer includes a first trench structure including a gate oxide layer formed around a first trench with poly-Si implant, a second trench structure including a gate oxide layer formed around a second trench with poly-Si implant, a p-base region formed between the first trench structure and the second trench structure, a plurality of n+ source region formed on the p-base region and between the first trench structure and the second trench structure, a dielectric layer formed on the first trench structure, the second trench structure, and the plurality of n+ source region. The frontside metal layer is formed on the semiconductor layer and filling gaps formed between the plurality of n+ source region on the p-base region.

Abstract: A power semiconductor device with drain voltage protection includes a semiconductor substrate, at least a trench gate transistor device and at least a trench ESD protection device. An upper surface of the semiconductor substrate has a first trench and a second trench. The trench gate transistor device is disposed in the first trench and the semiconductor substrate. The trench ESD protection device is disposed in the second trench, and includes a first doped region, a second doped region and a third doped region. The first doped region and the third doped region are respectively electrically connected to a drain and a gate of the trench gate transistor device.