TY - JOUR
T1 - Investigation into active-gate-driving performance and potential closed-loop controller implementations for silicon carbide MOSFET modules
AU - Şahin, İlker
AU - Parker, Mason
AU - Mathieson, Ross
AU - Finney, Stephen
AU - Judge, Paul D.
N1 - Publisher Copyright:
© 2024 The Authors. IET Power Electronics published by John Wiley & Sons Ltd on behalf of The Institution of Engineering and Technology.
PY - 2024/4/30
Y1 - 2024/4/30
N2 - Active gate driving (AGD) is a promising concept for achieving high-performance power transistor switching. This is particularly crucial for Silicon Carbide (SiC) MOSFETs since their inherently fast switching characteristics give rise to severe overshoots and oscillations which translate into increased levels of electromagnetic interference (EMI) emissions. In this paper, an AGD strategy using a single-pulse applied during the switching transient is considered for a 1200 V 400 A SiC MOSFET module. The effect of single-pulse timing, load current, and temperature on the switching performance is analyzed in detail. The radiated EMI reduction benefits are quantified by H-field and E-field probes. A conceptual closed-loop AGD approach is presented and compared to open-loop operation. For the transistor turn-off case under full load current of 400 A, experimental results show that it is possible to reduce voltage overshoot by 43.3%, voltage and current oscillations by 69.7% and 52.2% respectively, and EMI by 76.6%, with a trade-off in the switching energy by a relatively minor increase of 18.2%, compared to the conventional gate driving case. For the turn-on case, current overshoot was reduced by 32.7%, EMI by 52%, voltage and current oscillations by 54.6% and 52.8%, respectively, with a penalty of 50.9% increase in the switching loss.
AB - Active gate driving (AGD) is a promising concept for achieving high-performance power transistor switching. This is particularly crucial for Silicon Carbide (SiC) MOSFETs since their inherently fast switching characteristics give rise to severe overshoots and oscillations which translate into increased levels of electromagnetic interference (EMI) emissions. In this paper, an AGD strategy using a single-pulse applied during the switching transient is considered for a 1200 V 400 A SiC MOSFET module. The effect of single-pulse timing, load current, and temperature on the switching performance is analyzed in detail. The radiated EMI reduction benefits are quantified by H-field and E-field probes. A conceptual closed-loop AGD approach is presented and compared to open-loop operation. For the transistor turn-off case under full load current of 400 A, experimental results show that it is possible to reduce voltage overshoot by 43.3%, voltage and current oscillations by 69.7% and 52.2% respectively, and EMI by 76.6%, with a trade-off in the switching energy by a relatively minor increase of 18.2%, compared to the conventional gate driving case. For the turn-on case, current overshoot was reduced by 32.7%, EMI by 52%, voltage and current oscillations by 54.6% and 52.8%, respectively, with a penalty of 50.9% increase in the switching loss.
KW - driver circuits
KW - electromagnetic compatibility
KW - electromagnetic interference
KW - power semiconductor switches
KW - silicon compounds
KW - switching transients
UR - http://www.scopus.com/inward/record.url?scp=85192177343&partnerID=8YFLogxK
U2 - 10.1049/pel2.12698
DO - 10.1049/pel2.12698
M3 - Article
AN - SCOPUS:85192177343
SN - 1755-4535
JO - IET Power Electronics
JF - IET Power Electronics
ER -