This paper presents an experimental switching behaviour comparison of GaN HEMT and SiC MOSFET against their Si competitors, the Si SJ MOSFET and high speed Si IGBT, in the 650 V class. The devices are first compared using their respective datasheets. The test circuit is introduced and hard switching tests under inductive load are performed to reveal the switching performance of the devices. The differences in the switching behaviours of the devices are identified and discussed
Silicon carbide (SiC), new power switches (PSW) require new driver circuits which can take advantage...
The drive inverter represents a central component of an electric vehicle (EV) drive train, being res...
The better physical properties of the new wide bandgap (WBG) semiconductor devices, e.g. silicon car...
The conduction and switching losses of SiC and GaN power transistors are compared in this paper. Vol...
SiC and GaN power transistors switching energy are compared in this paper. In order to compare switc...
SiC and GaN power transistors conduction loss and switching losses are compared in this paper. In or...
The subject of this paper is the mutual comparison of switching energy losses in cascode gallium nit...
New GaN and SiC wide bandgap power devices offer impressively fast switching performance compared to...
International audienceSilicon (Si) power devices have dominated theworld of Power Electronics in the...
Present day applications using power electronic converters are focusing towards improving the speed,...
In this paper, benchmark of Si IGBT, SiC MOSFET and GaN HEMT power switches at 600V class is conduct...
This work presents a comparative analysis among four power MOSFET technologies: conventional Silicon...
Power semiconductor devices plays a major role in efficient power conversion. As we have Silicon (Si...
Wide bandgap (WBG) semiconductors, such as silicon carbide (SiC) and gallium nitride (GaN), exhibit ...
International audienceWide Bandgap devices allow building more compact power converters. To study th...
Silicon carbide (SiC), new power switches (PSW) require new driver circuits which can take advantage...
The drive inverter represents a central component of an electric vehicle (EV) drive train, being res...
The better physical properties of the new wide bandgap (WBG) semiconductor devices, e.g. silicon car...
The conduction and switching losses of SiC and GaN power transistors are compared in this paper. Vol...
SiC and GaN power transistors switching energy are compared in this paper. In order to compare switc...
SiC and GaN power transistors conduction loss and switching losses are compared in this paper. In or...
The subject of this paper is the mutual comparison of switching energy losses in cascode gallium nit...
New GaN and SiC wide bandgap power devices offer impressively fast switching performance compared to...
International audienceSilicon (Si) power devices have dominated theworld of Power Electronics in the...
Present day applications using power electronic converters are focusing towards improving the speed,...
In this paper, benchmark of Si IGBT, SiC MOSFET and GaN HEMT power switches at 600V class is conduct...
This work presents a comparative analysis among four power MOSFET technologies: conventional Silicon...
Power semiconductor devices plays a major role in efficient power conversion. As we have Silicon (Si...
Wide bandgap (WBG) semiconductors, such as silicon carbide (SiC) and gallium nitride (GaN), exhibit ...
International audienceWide Bandgap devices allow building more compact power converters. To study th...
Silicon carbide (SiC), new power switches (PSW) require new driver circuits which can take advantage...
The drive inverter represents a central component of an electric vehicle (EV) drive train, being res...
The better physical properties of the new wide bandgap (WBG) semiconductor devices, e.g. silicon car...
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