GaN-based half bridge power conversion circuits employ control, support and logic functions that are monolithically integrated on the same devices as the power transistors. In some embodiments a low side GaN device communicates through one or more level shift circuits with a high side GaN device. Both the high side and the low side devices may have one or more integrated control, support and logic functions. Some devices employ electro-static discharge circuits and features formed within the GaN-based devices to improve the reliability and performance of the half bridge power conversion circuits.

A semiconductor device includes a semiconductor substrate having a first side. At least a first doping region is formed in the semiconductor substrate. The first doping region has a laterally varying doping dosage and/or a laterally varying implantation depth.

An output MOS transistor has a drain connected with a power supply and a source connected with an output terminal. The short-circuit MOS transistor has a source connected with the output terminal. The short-circuit MOS transistor is formed in a semiconductor substrate connected with the power supply. A switching device is formed in a semiconductor region which is formed in the semiconductor substrate, and contains a first diffusion layer connected with the gate of the output MOS transistor and a second diffusion layer formed in the semiconductor region and connected with the drain of the short-circuit MOS transistor.

An integrated circuit (IC) device may include a first active transistor of a first-type in a first-type region. The first active transistor may have a first-type work function material and a low channel dopant concentration in an active portion of the first active transistor. The IC device may also include a first isolation transistor of the first-type in the first-type region. The second active transistor may have a second-type work function material and the low channel dopant concentration in an active portion of the first isolation transistor. The first isolation transistor may be arranged adjacent to the first active transistor.

In a semiconductor device connected to a mutual-inductive load, a voltage dividing diode is provided in series to an ST-MOS circuit so that an anode thereof is connected to a GND terminal and a cathode thereof is connected to the back gate of each of lateral nMOSFETs forming the ST-MOS circuit. This can inhibit parasitic transistors in the lateral nMOSFETs from malfunctioning to enable the voltage at an ST terminal to be reliably maintained at a normal voltage.

In accordance with an embodiment, semiconductor component includes a compound semiconductor material based semiconductor device coupled to a silicon based semiconductor device and a protection element, wherein the silicon based semiconductor device is a transistor. The protection element is coupled in parallel across the silicon based semiconductor device and may be a resistor, a diode, or a transistor. In accordance with another embodiment, the silicon based semiconductor device is a diode. The compound semiconductor material may be shorted to a source of potential such as, for example, ground, with a shorting element.

In an embodiment, an integrated circuit includes transistors in different active regions, electrically isolated using single diffusion break isolation. The single diffusion break isolation includes a first dummy transistor that has a different threshold voltage than the transistors in either active region for which the single diffusion break is creating isolation. The first dummy transistor may have lower leakage current than transistors in either active region, creating effective isolation between the active regions and consuming relatively small amounts of power due to the lower leakage currents.

In an embodiment, an integrated circuit includes transistors in different active regions, electrically isolated using single diffusion break isolation. The single diffusion break isolation includes a first dummy transistor that has a different threshold voltage than the transistors in either active region for which the single diffusion break is creating isolation. The first dummy transistor may have lower leakage current than transistors in either active region, creating effective isolation between the active regions and consuming relatively small amounts of power due to the lower leakage currents.

An HEMT that includes a hybrid gate contact comprising an enhancement gate portion and a depletion gate portion. The depletion gate portion acts as a buffer that reduces the large electric field peak that would have otherwise existed at the enhancement gate portion if there was no depletion gate portion. Instead, the large electric field peak is split into two smaller electric field peaks; the first smaller electric field peak being at the drain contact side of the depletion gate portion, and the second smaller electric field peak being at the drain contact side of the enhancement gate portion. The use of this hybrid gate contact allows for greater ability to regulate and reduce electric field peaks, thus allowing the overall size of the HEMT to be reduced, and/or allowing the HEMT to handle higher voltages and currents, as compared to an HEMT with only an enhancement gate.

A semiconductor device includes a depletion mode GaN FET and an integrated driver/cascode IC. The integrated driver/cascode IC includes an enhancement mode cascoded NMOS transistor which is connected in series to a source node of the GaN FET. The integrated driver/cascode IC further includes a driver circuit which conditions a gate input signal and provides a suitable digital waveform to a gate node of the cascoded NMOS transistor. The cascoded NMOS transistor and the driver circuit are formed on a same silicon substrate.