Abstract: An electrostatic discharge (ESD) protection structure that provides snapback protections to one or more high voltage circuit components. The ESD protection structure can be integrated along a peripheral region of a high voltage circuit, such as a high side gate driver of a driver circuit. The ESD protection structure includes a p-channel device and an n-channel device. The p-channel device includes an n-type barrier region circumscribing a p-type drain region with an n-type body region. The p-channel device may be positioned adjacent to the n-channel device and a high voltage junction diode.

Abstract: An electrostatic discharge (ESD) protection structure that provides snapback protections to one or more high voltage circuit components. The ESD protection structure can be integrated along a peripheral region of a high voltage circuit, such as a high side gate driver of a driver circuit. The ESD protection structure includes a bipolar transistor structure interfacing with a PN junction of a high voltage device, which is configured to discharge the ESD current during an ESD event. The bipolar transistor structure has a collector region overlapping the PN junction, a base region embedded with sufficient pinch resistance to launch the snapback protection, and an emitter region for discharging the ESD current.

Abstract: An electrostatic discharge (ESD) protection structure that provides snapback protections to one or more high voltage circuit components. The ESD protection structure can be integrated along a peripheral region of a high voltage circuit, such as a high side gate driver of a driver circuit. The ESD protection structure includes a p-channel device and an n-channel device. The p-channel device includes an n-type barrier region circumscribing a p-type drain region with an n-type body region. The p-channel device may be positioned adjacent to the n-channel device and a high voltage junction diode.

Abstract: In an example, a circuit includes a first power switch device coupled between a voltage input and an output terminal, the first power switch device having a control input. A voltage divider circuit includes a first resistor and a second resistor. The first resistor is coupled between the voltage input and a sense node between the first resistor and the second resistor. The second resistor has a first terminal coupled to the sense node and a second terminal. A second switch device is coupled between the second terminal of the second resistor and an electrical ground terminal. A voltage clamp is coupled between the sense node and the electrical ground terminal.

Abstract: In an example, a circuit includes a first power switch device coupled between a voltage input and an output terminal, the first power switch device having a control input. A voltage divider circuit includes a first resistor and a second resistor. The first resistor is coupled between the voltage input and a sense node between the first resistor and the second resistor. The second resistor has a first terminal coupled to the sense node and a second terminal. A second switch device is coupled between the second terminal of the second resistor and an electrical ground terminal. A voltage clamp is coupled between the sense node and the electrical ground terminal.

Abstract: An electrostatic discharge (ESD) protection structure that provides snapback protections to one or more high voltage circuit components. The ESD protection structure can be integrated along a peripheral region of a high voltage circuit, such as a high side gate driver of a driver circuit. The ESD protection structure includes a bipolar transistor structure interfacing with a PN junction of a high voltage device, which is configured to discharge the ESD current during an ESD event. The bipolar transistor structure has a collector region overlapping the PN junction, a base region embedded with sufficient pinch resistance to launch the snapback protection, and an emitter region for discharging the ESD current.

Abstract: Described examples include a semiconductor device having a resistor. The resistor includes a first terminal and a second terminal. The resistor also includes a first resistive element over an insulating layer over a substrate having a first end coupled to the first terminal of the resistor and a second end coupled to the second terminal of the resistor; and a parallel second resistive element over the insulating layer over the substrate having a first end coupled to the first terminal of the resistor and a second end coupled to the second terminal of the resistor. The resistor may also be coupled in series with another resistor.

Abstract: A semiconductor device includes a substrate including a semiconductor surface layer. A field plate (FP) includes a trench in the semiconductor surface layer filled with a single polysilicon layer positioned on at least one side of a power metal-oxide-semiconductor field effect transistor (power MOSFET). The power MOSFET includes a dielectric liner lining a sidewall of the trench under the polysilicon layer including a second dielectric liner on a first dielectric liner. An upper portion of the dielectric liner has a lower dielectric thickness as compared to a dielectric thickness on its lower portion. The single polysilicon layer extends continuously over the dielectric liner along both the lower portion and the upper portion. The power MOSFET includes a drain including a drain contact below a vertical drift region in the semiconductor surface layer, and a gate, body and a source above the vertical drift region.

Abstract: In some examples, a semiconductor device, comprises a semiconductor substrate; an epitaxial layer having a top side disposed on the semiconductor substrate, wherein the epitaxial layer has a source implant region, a drain implant region, a first doped region, and a second doped region, wherein the first doped region is adjacent to the source implant region and the second doped region is adjacent to the drain implant region, wherein the top side has a sloped surface over the second doped region; a gate electrode supported by the top side; a source electrode in contact with the source implant region; and a drain electrode in contact with the drain implant region.

Abstract: A semiconductor device has a semiconductor material in a substrate. The semiconductor device has an MOS transistor. A trench in the substrate extends from a top surface of the substrate) into the semiconductor material. A shield is disposed in the trench. The shield has a contact portion which extends toward a top surface of the trench. A gate of the MOS transistor is disposed in the trench over the shield. The gate is electrically isolated from the shield. The gate is electrically isolated from the contact portion of the shield by a shield isolation layer which covers an angled surface of the contact portion extending toward the top of the trench. Methods of forming the semiconductor device are disclosed.

Abstract: A semiconductor device includes a MOS transistor located within a semiconductor substrate of a first conductivity type. The transistor includes a body well located between a drain well and a substrate contact well. A buried voltage blocking region of a second conductivity type is located within the substrate and is connected to the body well. The buried voltage blocking region extends toward the substrate contact well, with an unmodified portion of the substrate remaining between the voltage blocking region and the substrate contact well.

Abstract: A semiconductor device includes a substrate including a semiconductor surface layer. A field plate (FP) includes a trench in the semiconductor surface layer filled with a single polysilicon layer positioned on at least one side of a power metal-oxide-semiconductor field effect transistor (power MOSFET). The power MOSFET includes a dielectric liner lining a sidewall of the trench under the polysilicon layer including a second dielectric liner on a first dielectric liner. An upper portion of the dielectric liner has a lower dielectric thickness as compared to a dielectric thickness on its lower portion. The single polysilicon layer extends continuously over the dielectric liner along both the lower portion and the upper portion. The power MOSFET includes a drain including a drain contact below a vertical drift region in the semiconductor surface layer, and a gate, body and a source above the vertical drift region.

Abstract: An integrated circuit containing a first plurality of MOS transistors operating in a low voltage range, and a second plurality of MOS transistors operating in a mid voltage range, may also include a high-voltage MOS transistor which operates in a third voltage range significantly higher than the low and mid voltage ranges, for example 20 to 30 volts. The high-voltage MOS transistor has a closed loop configuration, in which a drain region is surrounded by a gate, which is in turn surrounded by a source region, so that the gate does not overlap field oxide. The integrated circuit may include an n-channel version of the high-voltage MOS transistor and/or a p-channel version of the high-voltage MOS transistor. Implanted regions of the n-channel version and the p-channel version are formed concurrently with implanted regions in the first and second pluralities of MOS transistors.

Abstract: Described examples include a semiconductor device having a resistor. The resistor includes a first terminal and a second terminal. The resistor also includes a first resistive element over an insulating layer over a substrate having a first end coupled to the first terminal of the resistor and a second end coupled to the second terminal of the resistor; and a parallel second resistive element over the insulating layer over the substrate having a first end coupled to the first terminal of the resistor and a second end coupled to the second terminal of the resistor. The resistor may also be coupled in series with another resistor.

Abstract: A trench gate metal oxide semiconductor field effect transistor (MOSFET) device includes an epitaxial layer on a substrate both doped a first conductivity type. Active area trenches have polysilicon gates over a double shield field plate. A junction termination trench includes a single shield field plate in a junction termination area which encloses the active area that includes a retrograde dopant profile of the second conductivity type into the epitaxial layer in the junction termination area. Pbody regions of a second conductivity type are between active trenches and between the outermost active trench and the junction termination trench. Source regions of the first conductivity type are in the body regions between adjacent active trenches. Metal contacts are over contact apertures that extend through a pre-metal dielectric layer reaching the body region under the source region, the single shield field plate, and that couples together the polysilicon gates.

Abstract: An integrated circuit includes a trench gate MOSFET including MOSFET cells. Each MOSFET cell includes an active trench gate in an n-epitaxial layer oriented in a first direction with a polysilicon gate over a lower polysilicon portion. P-type body regions are between trench gates and are separated by an n-epitaxial region. N-type source regions are located over the p-type regions. A gate dielectric layer is between the polysilicon gates and the body regions. A metal-containing layer contacts the n-epitaxial region to provide an anode of an embedded Schottky diode. A dielectric layer over the n-epitaxial layer has metal contacts therethrough connecting to the n-type source regions, to the p-type body regions, and to the anode of the Schottky diode.

Abstract: A device includes a transistor formed on a substrate. The transistor includes an n-type drain contact layer, an n-type drain layer, an oxide layer, a p-type body region, a p-type terminal region, body trenches, and terminal trenches. The n-type drain contact layer is near a bottom surface of the substrate. The n-type drain layer is positioned on the n-type drain contact layer. The oxide layer circumscribes a transistor region. The p-type body region is positioned within the transistor region. The p-type terminal region extends from under the oxide layer to an edge of the transistor region, thereby forming a contiguous junction with the p-type body region. The body trenches is within the transistor region and interleaves with the p-type body region, whereas the terminal trenches is outside the transistor region and interleaves with the p-type terminal region.

Abstract: A device includes a laterally diffused MOSFET, which in turn includes n-type source and drain regions in a p-type semiconductor substrate. A gate electrode is located over the semiconductor substrate between the source region and the drain region. An isolation region is laterally spaced apart from the source region, and is bounded by an n-type buried layer and an n-type well region that reaches from a surface of the substrate to the buried layer. A p-type doped region and an n-type doped region are disposed within the isolation region, the p-type doped region and the n-type doped region forming a diode. A first conductive path connects the n-type doped region to the source region, and a second conductive path connects the p-type doped region to the gate electrode.

Abstract: A semiconductor device includes a MOS transistor located within a semiconductor substrate of a first conductivity type. The transistor includes a body well located between a drain well and a substrate contact well. A buried voltage blocking region of a second conductivity type is located within the substrate and is connected to the body well. The buried voltage blocking region extends toward the substrate contact well, with an unmodified portion of the substrate remaining between the voltage blocking region and the substrate contact well.

Abstract: An integrated circuit chip includes a bimodal power N-P-Laterally Diffused Metal Oxide Semiconductor (LDMOS) device having an N-gate coupled to receive an input signal and a level shifter coupled to receive the input signal and to provide a control signal to a P-gate driver of the N-P-LDMOS device. A method of operating an N-P-LDMOS power device is also disclosed.