There is a problem that an area of a principal current cell is reduced by an area of a bonding pad wiring layer for a sub-cell. A source electrode 9b of a current detection cell 22 is electrically connected to a bonding pad wiring layer 12 formed on an interlayer insulating film 10 via a wiring layer contact 11. The bonding pad wiring layer 12 is formed with respect to a source electrode 9a of a principal current cell 21 so as to cover a part of the source electrode 9a via the interlayer insulating film 10. As a result, the source electrode 9b is miniaturized, and a size of the source electrode 9b is made substantially equal to a size of the current detection cell 22. Therefore, the current detection cell 22 and the principal current cell 21 are disposed close to each other.

An apparatus includes a drift region formed over the substrate, a body region over the substrate, a first well region formed over the drift region, a collector region formed in the first well region, an emitter region formed in the body region, a first body contact formed in the body region, a first gate situated between the collector region and the emitter region, a second well region formed over the substrate, a drain region formed in the second well region, wherein the drain region and the emitter region are electrically connected to each other, a source region formed in the second well region, wherein the source region and the first body contact are electrically connected to each other, and a second gate situated between the drain region and the source region, wherein the second gate and the first gate are electrically connected to each other.

A wide band gap semiconductor device includes a semiconductor layer, a trench formed in the semiconductor layer, first, second, and third regions having particular conductivity types and defining sides of the trench, and a first electrode embedded inside an insulating film in the trench. The second region integrally includes a first portion arranged closer to a first surface of the semiconductor layer than to a bottom surface of the trench, and a second portion projecting from the first portion toward a second surface of the semiconductor layer to a depth below a bottom surface of the trench. The second portion of the second region defines a boundary surface with the third region, the boundary region being at an incline with respect to the first surface of the semiconductor layer.

Provided is a semiconductor device, comprising: a semiconductor substrate; a transistor portion including an emitter region on the top of the semiconductor substrate; a diode portion including a cathode region on the bottom of the semiconductor substrate and a second conductivity type overlap region in a region other than the cathode region and arranged alongside to the transistor portion a preset arrangement direction on the top of the semiconductor substrate; and an interlayer dielectric film provided between the semiconductor substrate and an emitter electrode and including a contact hole for connecting the emitter electrode and the diode portion. The overlap region is provided to have a first length between the end of the emitter region and the end of the cathode region and a second length, which is shorter than the first length, between the end of the contact hole and the end of the cathode region.

A fabrication method for a semiconductor device includes measuring a thickness of a semiconductor substrate in which a bulk donor of a first conductivity type is entirely distributed, adjusting an implantation condition in accordance with the thickness of the semiconductor substrate and implanting hydrogen ions from a lower surface of the semiconductor substrate to an upper surface side of the semiconductor substrate, and annealing the semiconductor substrate and forming, in a passage region through which the hydrogen ions have passed, a first high concentration region of the first conductivity type in which a donor concentration is higher than a doping concentration of the bulk donor.

A transistor includes a plurality of gate fingers that extend in a first direction and are spaced apart from each other in a second direction, each of the gate fingers comprising at least spaced-apart and generally collinear first and second gate finger segments that are electrically connected to each other. The first gate finger segments are separated from the second gate finger segments in the first direction by a gap region that extends in the second direction. A resistor is disposed in the gap region.

A semiconductor integrated circuit device including standard cells including fin transistors includes, at a cell row end, a cell-row-terminating cell that does not contribute to a logical function of a circuit block. The cell-row-terminating cell includes a plurality of fins extending in an X direction. Ends of the plurality of fins on the inner side of the circuit block are near a gate structure placed at a cell end and do not overlap with the gate structure in a plan view, and ends of the plurality of fins on an outer side of the circuit block overlap with any one of a gate structure in a plan view.

A method of current detection includes providing a transistor arrangement which comprises a drift and drain region arranged in a semiconductor body and each connected to a drain node, a plurality of load transistor cells each having a source region integrated in a first region of the semiconductor body, a plurality of sense transistor cells each having a source region integrated in a second region of the semiconductor body, a first source node electrically connected to the source region of each of the plurality of the load transistor cells via a first source conductor, and a second source node electrically connected to the source region of each of the plurality of the sense transistor cells via a second source conductor; and detecting a first current flowing between the drain node and the first source node of the transistor arrangement, wherein detecting the first current includes measuring a second current flowing between the drain node and the second source node of the transistor arrangement.

A method of producing a silicon carbide (SiC) device includes: forming a stripe-shaped trench gate structure that extends from a first surface of a SiC body into the SiC body, the gate structure having a gate length along a lateral first direction, a bottom surface and a first gate sidewall of the gate structure being connected via a first bottom edge of the gate structure; forming at least one source region of a first conductivity type; and forming a shielding region of a second conductivity type in contact with the first bottom edge of the gate structure across at least 20% of the gate length. Forming the shielding region includes: forming a deep shielding portion; and forming a top shielding portion between the first surface and the deep shielding portion, the top shielding portion being in contact with the first bottom edge.

A transistor device includes: a semiconductor body having opposing first and second surfaces; an edge termination region laterally surrounding an active area; a drain region of a first conductivity type at the second surface; and a drift region of the first conductivity type on the drain region. In the active area, a body region of a second conductivity type is on the drift region, a source region of the first conductivity type is on the body region, and at least one gate electrode is positioned in a gate trench that extends into the semiconductor body from the first surface. A superjunction structure includes columns of the second conductivity type extending into the semiconductor body substantially perpendicular to the first surface in the active area and edge termination region. A first contact extends through the body region for each second conductivity type column in the active region and is electrically conductive.