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Silicon Carbide (SiC) power devices with super-cascode structure provide a cost-effective solution for high performance medium voltage power switches. However, these SiC super-cascode devices are still in the early development stage, and limited information on the device characteristics is available. This paper presents the characterization and evaluation of a 4.5 kV, 40 A SiC super-cascode device...
This paper presents an evaluation of a newly released power stage direct drive GaN HEMT. The double pulse test is performed and the dynamic performance is characterized. PCB layout optimization is also investigated for improved switching transients. It is shown that the direct drive system provides simplified circuit design, reduced number of external components, and small gate loop parasitics. Also,...
In this paper, a comprehensive evaluation work on 1.7 kV SiC Super Junction Transistor (SJT) power module and 1.7 kV SiC MOSFET power modules is presented. Both device static and dynamic performance is extracted and compared at wide device current range and temperature range. The data presented in this paper can be used as input for medium voltage power conversion system power transistor selection,...
With the rapid development of wide bandgap power transistor technology, the latest gallium-nitride based power transistors are able to be used as the main switches in the high power (≥10 kW) conversion systems. In order to achieve the desired high efficiency and higher power density successfully, the entire GaN based power conversion system needs to take multiple considerations into the design stage...
The medium power rating two-level three phase voltage source inverter is among the most popular power conversion systems. The typical switching frequency of the commercial medium power rating inverter, however, is limited to tens of kHz. By increasing the switching frequency and using emerging gallium-nitride devices, the size of the overall system can be greatly reduced. This paper begins by reviewing...
This paper presents a 15kV silicon carbide (SiC) MOSFET gate drive, which features high common-mode (CM) noise immunity, small size, light weight, and robust yet flexible protection functions. To enhance the gate-drive power reliability, a power over fiberbased isolated power supply is designed to replace the traditional design based on isolation transformer. It delivers the gate-drive power by laser...
This paper presents a 15 kV SiC MOSFET gate drive circuit, which features high common-mode (CM) noise immunity, small size, light weight, and robust yet flexible protection functions. To enhance the gate-drive power reliability, a power over fiber (PoF) based isolated power supply is designed to replace the traditional design based on isolation transformer. It delivers the gate-drive power by laser...
In this paper, we present a comprehensive evaluation of the latest 600 V class Gallium Nitride based Gate Injection Transistor (GaN-GIT) for high temperature and high efficiency applications. In this study, the Panasonic GITs are used as the reference for latest GaN-GIT technology. Static and dynamic testing was performed on the two GaN-GIT versions to extract critical static parameters and switching...
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