A lateral double-diffused metal-oxide-semiconductor (LDMOS) transistor including a breakdown voltage clamp includes a drain n+ region, a source n+ region, a gate, and a p-type reduced surface field (PRSF) layer including one or more bridge portions. Each of the one or more bridge portions extends below the drain n+ region in a thickness direction. Another LDMOS transistor includes a drain n+ region, a source n+ region, a gate, an n-type reduced surface field (NRSF) layer disposed between the source n+ region and the drain n+ region in a lateral direction, a PRSF layer disposed below the NRSF layer in a thickness direction orthogonal to the lateral direction, and a p-type buried layer (PBL) disposed below the PRSF layer in the thickness direction. The drain n+ region is disposed over the PBL in the thickness direction.

A semiconductor device includes: a pad; a control circuit; a plurality of high-potential-side circuit regions having distances to the pad different from each other, each including a gate drive circuit, a SET-side level shifter, a RESET-side level shifter, and a circular wire; a SET-side wire electrically connects the pad with the SET-side level shifters; and a RESET-side wire electrically connects the pad with the RESET-side level shifters, wherein the circular wire located closer to the pad is electrically connected to the SET-side wire and the RESET-side wire via the circular wire 8u located further from the pad.

A semiconductor integrated circuit includes: a p.sup.−-type semiconductor substrate defining a high-potential side circuit area and a low-potential side circuit area separated from each other; a high-side n well provided in an upper part of the semiconductor substrate in the high-potential side circuit area; a high-side p well provided in the high-side n well; and a p-type semiconductor region provided in an upper part of the semiconductor substrate in the low-potential side circuit area; and n.sup.+-type semiconductor region provided to be brought contact with the p-type semiconductor region, wherein a whole n-type semiconductor region including the n.sup.+-type semiconductor region, has an impurity concentration higher than an impurity concentration of the high-side n well.

A reverse-conducting MOS device is provided having an active cell region and a termination region. Between a first and second main side. The active cell region comprises a plurality of MOS cells with a base layer of a second conductivity type. On the first main side a bar of the second conductivity type, which has a higher maximum doping concentration than the base layer, is arranged between the active cell region and the termination region, wherein the bar is electrically connected to the first main electrode. On the first main side in the termination region a variable-lateral-doping layer of the second conductivity type is arranged. A protection layer of the second conductivity type is arranged in the variable-lateral-doping layer, which protection layer has a higher maximum doping concentration than the maximum doping concentration of the variable-lateral-doping layer in a region attached to the protection layer.

A hybrid transistor circuit is disclosed for use in III-Nitride (III-N) semiconductor devices, comprising a Silicon (Si)-based Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET), a Group III-Nitride (III-N)-based Field-Effect Transistor (FET), and a driver unit. A source terminal of the III-N-based FET is connected to a drain terminal of the Si-based MOSFET. The driver unit has at least one input terminal, and two output terminals connected to the gate terminals of the transistors respectively. The hybrid transistor circuit is turned on through the driver unit by switching on the Silicon-based MOSFET first before switching on the III-N-based FET, and is turned off through the driver unit by switching off the III-N-based FET before switching off the Silicon-based MOSFET. Also disclosed are integrated circuit packages and semiconductor structures for forming such hybrid transistor circuits. The resulting hybrid circuit provides power-efficient and robust use of III-Nitride semiconductor devices.

A transistor arrangement includes: a layer stack with first and second semiconductor layers of complementary first and second doping types; a first source region of a first transistor device adjoining the first semiconductor layers; a first drain region of the first transistor device adjoining the second semiconductor layers and spaced apart from the first source region; gate regions of the first transistor device, each gate region adjoining at least one second semiconductor layer, being arranged between the first source region and the first drain region, and being spaced apart from the first source region and the first drain region; a third semiconductor layer adjoining the layer stack and each of the first source region, first drain region, and each gate region; and active regions of a second transistor device integrated in the third semiconductor layer in a second region spaced apart from a first region of the third semiconductor layer.

A lateral double-diffused metal-oxide-semiconductor (LDMOS) transistor including a breakdown voltage clamp includes a drain n+ region, a source n+ region, a gate, and a p-type reduced surface field (PRSF) layer including one or more bridge portions. Each of the one or more bridge portions extends below the drain n+ region in a thickness direction. Another LDMOS transistor includes a drain n+ region, a source n+ region, a gate, an n-type reduced surface field (NRSF) layer disposed between the source n+ region and the drain n+ region in a lateral direction, a PRSF layer disposed below the NRSF layer in a thickness direction orthogonal to the lateral direction, and a p-type buried layer (PBL) disposed below the PRSF layer in the thickness direction. The drain n+ region is disposed over the PBL in the thickness direction.

A semiconductor device includes a semiconductor layer that has a main surface, a trench gate structure that includes a trench formed in the main surface and having a first sidewall at one side, a second sidewall at the other side and a bottom wall in a cross-sectional view, an insulation layer formed on an inner wall of the trench, and a gate electrode embedded in the trench with the insulation layer between the trench and the gate electrode and having an upper end portion positioned at a bottom-wall side with respect to the main surface, a plurality of first-conductivity-type drift regions that are respectively formed in a region at the first sidewall side of the trench and in a region at the second sidewall side of the trench such as to face each other with the trench interposed therebetween in a surface layer portion of the main surface and that are positioned in a region at the main surface side with respect to the bottom wall, and a plurality of first-conductivity-type source/drain regions that are formed in surface layer portions of the plurality of drift regions, respectively.

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.

A semiconductor device includes: a pad; a control circuit; a plurality of high-potential-side circuit regions having distances to the pad different from each other, each including a gate drive circuit, a SET-side level shifter, a RESET-side level shifter, and a circular wire; a SET-side wire electrically connects the pad with the SET-side level shifters; and a RESET-side wire electrically connects the pad with the RESET-side level shifters, wherein the circular wire located closer to the pad is electrically connected to the SET-side wire and the RESET-side wire via the circular wire 8u located further from the pad.