In a semiconductor device having a main cell region and a sense cell region, a main contact trench and a sense contact trench extend in one direction. When viewed from a stacking direction of a drift layer and a body layer, in the one direction, the main contact trench and a first impurity region disposed in the main cell region protrude more than a main upper electrode toward a sense upper electrode, and the sense contact trench and the first impurity region disposed in the sense cell region protrude more than the sense upper electrode toward the main upper electrode.

A semiconductor device includes a semiconductor chip, and an n-system gate divided transistor, where the “n” is not less than 2, that includes n-number of system transistors formed in the semiconductor chip such as to be individually controlled and that is configured such as to generate a single output signal by selective controls of the n-number of system transistors.

A semiconductor device 100 has a power transistor N1 of vertical structure and a temperature detection element 10a configured to detect abnormal heat generation by the power transistor N1. The power transistor N1 includes a first electrode 208 formed on a first main surface side (front surface side) of a semiconductor substrate 200, a second electrode 209 formed on a second main surface side (rear surface side) of the semiconductor substrate 200, and pads 210a-210f positioned unevenly on the first electrode 208. The temperature detection element 10a is formed at a location of the highest heat generation by the power transistor N1, the location (near the pad 210b where it is easiest for current to be concentrated) being specified using the uneven positioning of the pads 210a-210f.

A performance of a semiconductor device including a main MOSFET and a sensing MOSFET having a double-gate structure including a gate electrode and a field plate electrode inside a trench is improved. A main MOSFET including a gate electrode and a field plate electrode inside a second trench and a sensing MOSFET for electric-current detection including a gate electrode and a field plate electrode inside a fourth trench are surrounded by different termination rings, respectively.

Between a source electrode (25) of a main device (24) and a current sensing electrode (22) of a current detection device (21), a resistor for detecting current is connected. Dielectric withstand voltage of gate insulator (36) is larger than a product of the resistor and maximal current flowing through the current detection device (21) with reverse bias. A diffusion length of a p-body region (32) of the main device (24) is shorter than that of a p-body (31) of the current detection device (21). A curvature radius at an end portion of the p-body region (32) of the main device (24) is smaller than that of the p-body (31) of the current detection device (21). As a result, at the inverse bias, electric field at the end portion of the p-body region (32) of the main device (24) becomes stronger than that of the p-body region (31) of the current detection device (21). Consequently, avalanche breakdown tends to occur earlier in the main device 24 than the current detection device (21).

A silicon carbide semiconductor device includes: a dummy sense region; and a drift layer of a first conductivity type, wherein a MOSFET with a built-in SBD including a first well region of a second conductivity type connected to a source electrode is formed in an active region, a MOSFET with a built-in SBD including a second well region of a second conductivity type connected to a sense pad is formed in an active sense region, and a third well region of a second conductivity type which is not ohmic-connected to any of the source electrode and the sense pad is formed on an upper layer part of the n-type drift layer in the dummy sense region. A gate electrode of the MOSFET with the built-in SBD in the active region and the MOSFET with the built-in SBD in the active sense region is connected to a gate pad.

A silicon carbide MOSFET device includes a gate pad area, a main MOSFET area and a secondary MOSFET area. A main source contact is electrically coupled to the source region of each of the main MOSFETs, and a separate secondary source contact is electrically coupled to the source region of each of the secondary MOSFETs. A gate contact electrically connects to each of the insulated gate members of the main and secondary MOSFETs. An asymmetric gate clamping circuit is coupled between the secondary source contact and the gate contact. In a first mode of operation of the MOSFET device the main source contact is electrically coupled with the secondary source contact to activate the gate clamping circuit. When activated, the circuit clamping a gate-to-source voltage to a first clamp voltage in an on-state of the MOSFET device, and to a second clamp voltage in an off-state of the MOSFET device.

A transistor arrangement includes a drift and drain region arranged in a semiconductor body and each connected to a drain node, a plurality of load transistor cells each comprising a source region integrated in a first region of the semiconductor body, a plurality of sense transistor cells each comprising 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 wherein a resistance of the second source conductor is different from a resistance of the first source conductor.

A semiconductor device includes a trench-type switching element formed in an active region and a trench-type current sense element formed in a current sense region. Below a trench in which a gate electrode of the switching element is embedded, a trench in which a gate electrode of the current sense element is embedded, and a trench formed at the boundary portion between the active region and the current sense region, protective layers are formed, respectively. The protective layer at the boundary portion between the active region and the current sense region has a divided portion that is divided in a direction from the active region to the current sense region.

A semiconductor device 100 has a power transistor N1 of vertical structure and a temperature detection element 10a configured to detect abnormal heat generation by the power transistor N1. The power transistor N1 includes a first electrode 208 formed on a first main surface side (front surface side) of a semiconductor substrate 200, a second electrode 209 formed on a second main surface side (rear surface side) of the semiconductor substrate 200, and pads 210a-210f positioned unevenly on the first electrode 208. The temperature detection element 10a is formed at a location of the highest heat generation by the power transistor N1, the location (near the pad 210b where it is easiest for current to be concentrated) being specified using the uneven positioning of the pads 210a-210f.