A system comprises: an inverter configured to convert DC power from a battery to AC power to drive a motor, wherein the inverter includes: a power switch including a drain terminal, a source terminal, and a gate terminal; and a controller configured to detect a change in current at the source terminal of the power switch using a complex impedance of a metal trace connected to the source terminal of the power switch, and control a gate control signal to the gate terminal based on the detected change in current.

A semiconductor guide pin is disclosed. Specific implementations may include a heatsink, one or more substrates coupled together, one or more pressfit pins coupled to the one or more substrates, and two or more guide pins coupled to the one or more substrates, where the two or more guide pins may have a height greater than the one or more pressfit pins.

A semiconductor unit includes: a semiconductor module including a semiconductor device and a horizontal terminal; a base plate including an upper surface to which the semiconductor module is bonded and a plurality of screw holes passing through the base plate from the upper surface to a lower surface; a cooler attached to the lower surface of the base plate and cooling the semiconductor module; and a plurality of screws screwed to the plurality of screw holes of the base plate, respectively, so that the cooler is attached to the lower surface of the base plate. A spot facing part having a depth smaller than a thickness of the base plate is provided to a part of at least one of the plurality of screw holes on a side of the upper surface of the base plate.

A power module includes: a first substrate having an outer surface and an inner surface; a semiconductor die coupled to the inner surface of the first substrate; a second substrate having an outer surface and an inner surface, the semiconductor die being coupled to the inner surface of the second substrate; and a first electrically conductive spacer coupled to inner surface of the first substrate and to the inner surface of the second substrate.

A system includes: an inverter configured to convert DC power to AC power, wherein the inverter includes: a power module including: a first substrate, a second substrate including a source plane and a gate plane separated from the source plane by a full trench, the source plane including a step trench, and the gate plane including an electrical connection through the second substrate to a gate input connection of the power module, a semiconductor die disposed between the first substrate and the second substrate, the step trench formed in a portion of the source plane corresponding to an edge of the semiconductor die, and the semiconductor die including a gate connected to the gate plane, and a sinter element disposed between the semiconductor die and the second substrate to connect the semiconductor die to the second substrate; a battery; and a motor.

A semiconductor assembly includes a semiconductor element designed as a power semiconductor module and comprising a contact, and a connection element designed as a busbar which is connected to the contact of the power semiconductor module via a force-fit connection, in particular a screw connection. The busbar includes a cover plate and a closed cooling channel structure with a cooling channel which is produced at least partially by an FSC (Friction Stir Channeling) method and arranged to run through the cover plate.

A semiconductor assembly includes a semiconductor element designed as a power semiconductor module and comprising a contact, and a connection element designed as a busbar which is connected to the contact of the power semiconductor module via a force-fit connection, in particular a screw connection. The busbar includes a cover plate and a closed cooling channel structure with a cooling channel which is produced at least partially by an FSC (Friction Stir Channeling) method and arranged to run through the cover plate.

The invention provides a heat dissipation module and an electronic device. The heat dissipation module includes a thermally conductive plastic member and a metal member. The thermally conductive plastic member includes a base and a plurality of heat dissipation fins. The base includes an upper surface and a lower surface opposite to each other, and the heat dissipation fins are arranged at intervals at the upper surface. The metal member is disposed at the lower surface of the base. The thermally conductive plastic member and the metal member are combined via insert molding. One of the thermally conductive plastic member and the metal member includes a plurality of heat dissipation bosses separated from each other, and the heat dissipation bosses are located at the lower surface of the base of the thermally conductive plastic member or at a surface of the metal member relatively far away from the base.

A semiconductor device includes a cooling base board and an insulated circuit substrate. On a front surface of an insulated board on the insulated circuit substrate, a high potential circuit pattern on which a semiconductor chip is mounted, an intermediate potential circuit pattern on which a semiconductor chip is mounted, a low potential circuit pattern, and a control circuit pattern are disposed so as to straddle a center line of the cooling base board. The intermediate potential circuit pattern includes a second chip mounting region, an output wiring connection region and an interconnect wiring region that form a U-shaped portion in which the high potential circuit pattern having a semiconductor chip thereon is disposed. The control circuit pattern is disposed so as to straddle the center line and faces the opening of the U-shaped portion.

A semiconductor device includes a cooling base board and an insulated circuit substrate. On a front surface of an insulated board on the insulated circuit substrate, a high potential circuit pattern on which a semiconductor chip is mounted, an intermediate potential circuit pattern on which a semiconductor chip is mounted, a low potential circuit pattern, and a control circuit pattern are disposed so as to straddle a center line of the cooling base board. The intermediate potential circuit pattern includes a second chip mounting region, an output wiring connection region and an interconnect wiring region that form a U-shaped portion in which the high potential circuit pattern having a semiconductor chip thereon is disposed. The control circuit pattern is disposed so as to straddle the center line and faces the opening of the U-shaped portion.