Abstract: A semiconductor device having cells is provided, with each cell including a gate. The device includes a gate pad, a gate busbar and gate lines. The busbar connects the gate pad to the gate lines, the gate lines connect the gate busbar to the gates of the cells, and each of the gate lines is disposed along a first axis. The gate busbar includes first portions each disposed along a second axis, and the second axis intersects with the first axis. The first portions are spaced apart from each other to divide the semiconductor device into emitter segments. Lengths of the emitter segments along the first axis changes with distances of the segments from the gate pad, so that gate signals arriving at the gates of the cells from the gate pad via the gate busbar and the gate lines are substantially consistent.

Abstract: A semiconductor device having cells is provided, with each cell including a gate. The device includes a gate pad, a gate busbar and gate lines. The busbar connects the gate pad to the gate lines, the gate lines connect the gate busbar to the gates of the cells, and each of the gate lines is disposed along a first axis. The gate busbar includes first portions each disposed along a second axis, and the second axis intersects with the first axis. The first portions are spaced apart from each other to divide the semiconductor device into emitter segments. Lengths of the emitter segments along the first axis changes with distances of the segments from the gate pad, so that gate signals arriving at the gates of the cells from the gate pad via the gate busbar and the gate lines are substantially consistent.

Abstract: A multi-finger high-electron mobility transistor and a method of manufacturing such a transistor, and an electronic device including such a transistor is provided. According to an aspect of the present disclosure, an etching step for reducing donor layer thickness and/or performing an ion implantation is used for locally reducing the 2DEG concentration.

Abstract: The present disclosure relates to a semiconductor device, and associated method of manufacture. The semiconductor device includes, MOSFET integrated with a p-n junction, the p-n junction arranged as a clamping diode across a source contact and a drain contact of the MOSFET. The MOSFET defines a first breakdown voltage and the clamping diode defines a second breakdown voltage, with the first breakdown voltage being greater than the second breakdown voltage so that the clamp diode is configured and arranged to receive a low avalanche current and the MOSFET is configured and arranged to receive a high avalanche current.

Abstract: The present disclosure relates to a semiconductor device, and associated method of manufacture. The semiconductor device includes, MOSFET integrated with a p-n junction, the p-n junction arranged as a clamping diode across a source contact and a drain contact of the MOSFET. The MOSFET defines a first breakdown voltage and the clamping diode defines a second breakdown voltage, with the first breakdown voltage being greater than the second breakdown voltage so that the clamp diode is configured and arranged to receive a low avalanche current and the MOSFET is configured and arranged to receive a high avalanche current.

Abstract: A trench gate field effect device has a semiconductor body (2) with a trench (3) extending into a first major surface (2a) so as to define a regular array of polygonal source cells (4). Each source cell contains a source region (5a,5b) and a body region (6a,6b) with the body regions separating the source regions from a common further region (20). A gate (G) extends within and along said trench (3) for controlling a conduction channel through each of the body regions. Each source cell (4) has a central semiconductor region (60) which is more highly doped than said body regions, is of opposite conductivity type to the further region and forms a diode with the further region. Each source cell (4) has an inner trench boundary (3a) and an outer polygonal trench boundary (3b) with the inner trench boundary bounding a central subsidiary cell (10a) containing the central semiconductor region (60).