Described examples include an integrated circuit having a semiconductor substrate. The integrated circuit has a transistor that includes a buried layer having within the substrate, the buried layer defining a drift region between the buried layer and the top surface and a body region in the substrate extending from the buried layer to the surface of the substrate. The transistor also having a source formed in the body region, a drain extending from the buried layer to the surface of the substrate, a drift well extending from the buried layer toward the top surface and extending from the body region to the drain, a drift surface layer located between the drift well and the top, and a gate proximate to the surface of the substrate at the body region.

A high-voltage semiconductor device includes a substrate, a body region, a well region, a bulk region, a source, a drain, an isolation region, a gate structure, and a resistor. The body region and the well region are disposed in the substrate. The bulk region and the source are disposed in the body region. The drain is disposed in the well region. The isolation region is disposed on the well region. The isolation region is disposed between the drain and the source. The gate structure is disposed on the substrate. The gate structure extends onto a portion of the isolation region. The resistor is disposed on the isolation region. The resistor is electrically connected to the bulk region and the drain, or the resistor is electrically connected to the drain and/or the source.

An apparatus includes a first lateral diffusion field effect transistor (LDFET) having a first threshold voltage and that includes a first gate electrode, a first drain contact, a first source contact, and a first electrically conductive shield plate separated from the first gate electrode and the first source contact by a first interlayer dielectric. A second LDFET of the apparatus has a second threshold voltage and includes a second gate electrode, a second drain contact, and a second source contact. The second source contact is electrically connected to the first source contact of the first LDFET. A control circuit of the apparatus is electrically coupled to the first electrically conductive shield plate and is configured to apply to the first electrically conductive shield plate a first gate bias voltage of a first level to set the first threshold voltage of the first LDFET to a first desired threshold voltage.

The semiconductor device configures a cascode-type high voltage element comprising a plurality of low voltage elements connected in series, wherein the number of stages of connected low voltage elements is reduced, and the high voltage element has desired withstand voltage, without limiting the withstand voltage of the gate oxide film of the low voltage elements. The semiconductor device comprises a first semiconductor element and one or more second semiconductor elements connected in series, wherein the first and the second semiconductor elements have a control signal output terminal between a source terminal and a drain terminal or between an emitter terminal and a collector terminal; and a gate terminal of the one or more second semiconductor elements is connected to the control signal output terminal of the first or second semiconductor element connected in series adjacently to the source or emitter side of said one or more second semiconductor elements.

In some embodiments, the present disclosure relates to an integrated chip that includes a source region and a drain region arranged over and/or within a substrate. Further, a shallow trench isolation (STI) structure is arranged within the substrate and between the source and drain regions. A gate electrode is arranged over the substrate, over the STI structure, and between the source and drain regions. A portion of the gate electrode extends into the STI structure such that a bottommost surface of the portion of the gate electrode is arranged between a topmost surface of the STI structure and a bottommost surface of the STI structure.

A fin-shaped field-effect transistor (finFET) device is provided. The finFET device includes a substrate material with a first surface and a bottom surface. The finFET device also includes a well region formed in the substrate material. The well region may include a first type of dopant. The finFET device also includes a fin structure disposed on the first surface of the substrate material. A portion of the fin structure may include the first type of dopant. The finFET device also includes an oxide material disposed on the first surface of the substrate material and adjacent to the portion of the fin structure. The finFET device also includes a first epitaxial material disposed over a portion of the fin structure. The first epitaxial material may include a second type of dopant.

A high-voltage semiconductor device includes a substrate, a body region, a well region, a bulk region, a source, a drain, an isolation region, a gate structure, and a resistor. The body region and the well region are disposed in the substrate. The bulk region and the source are disposed in the body region. The drain is disposed in the well region. The isolation region is disposed on the well region. The isolation region is disposed between the drain and the source. The gate structure is disposed on the substrate. The gate structure extends onto a portion of the isolation region. The resistor is disposed on the isolation region. The resistor is electrically connected to the bulk region and the drain, or the resistor is electrically connected to the drain and/or the source.

An integrated power semiconductor device, includes devices integrated on a single chip. The devices include a vertical high voltage device, a first high voltage pLDMOS device, a high voltage nLDMOS device, a second high voltage pLDMOS device, a low voltage NMOS device, a low voltage PMOS device, a low voltage NPN device, and a low voltage diode device. A dielectric isolation is applied to the first high voltage pLDMOS device, the high voltage nLDMOS device, the second high voltage pLDMOS device, the low voltage NMOS device, the low voltage PMOS device, the low voltage NPN device, and the low voltage diode device. A multi-channel design is applied to the first high voltage pLDMOS device, and the high voltage nLDMOS device. A single channel design is applied to the second high voltage pLDMOS device.

An apparatus includes a first lateral diffusion field effect transistor (LDFET) having a first threshold voltage and that includes a first gate electrode, a first drain contact, a first source contact, and a first electrically conductive shield plate separated from the first gate electrode and the first source contact by a first interlayer dielectric. A second LDFET of the apparatus has a second threshold voltage and includes a second gate electrode, a second drain contact, and a second source contact. The second source contact is electrically connected to the first source contact of the first LDFET. A control circuit of the apparatus is electrically coupled to the first electrically conductive shield plate and is configured to apply to the first electrically conductive shield plate a first gate bias voltage of a first level to set the first threshold voltage of the first LDFET to a first desired threshold voltage.

A transistor device includes a substrate a first transistor structure. The first transistor structure includes a first fin structure on the substrate. The first fin structure includes a first doped region, and a second fin structure on the substrate spaced apart from the first fin structure. The second fin structure includes a second doped region and a third doped region spaced apart from the second doped region. The transistor device includes a first electrode on the second fin structure and covering a first end of the second fin structure.