TY - JOUR
T1 - Design automation using exclusion-based hierarchical computation for power electronics converters in harsh environments
AU - Xiao, Yudi
AU - Zhang, Zhe
AU - Zsurzsan, Gabriel
AU - Andersen, Michael A.E.
AU - MacFadyen, Martin
AU - Liao, Yuchuan
AU - Pena Alzola, Rafael
AU - Yuan, Weijia
AU - Zhang, Min
PY - 2024/8/15
Y1 - 2024/8/15
N2 - Designing power electronics converters for harsh environments is challenging due to the absence of components’ performance under harsh conditions, the frequent transition and data-passing among various software, and the time-consuming and computationally heavy work flow. This paper promotes using design automation to address the aforementioned design challenges. The implementations include public-accessible component databases, automated co-action among circuit simulators and finite element simulations to perform electrical, electromagnetic and thermal co-design, and finally an exclusion-based work flow with hierarchical computation to reduce computational load. The theorized framework is exemplified on designing a real world 175 ◦C 1.5kW Three-level Neutral-point-clamped dc-dc converter. A database containing the high-temperature characteristics of SiC MOSFETs and ferrites is established and shared through a web application with graphical user interface. In 310 min, the program, which includes computationally heavy 3D finite element simulation, delivers design output after evaluating the converter’s electrical, electromagnetic and thermal performance under 10 million parameter sets. Finally, a 1.5kW dc-dc converter prototype is built and tested in 175 ◦C ambient temperature to verify the quality of the design output.
AB - Designing power electronics converters for harsh environments is challenging due to the absence of components’ performance under harsh conditions, the frequent transition and data-passing among various software, and the time-consuming and computationally heavy work flow. This paper promotes using design automation to address the aforementioned design challenges. The implementations include public-accessible component databases, automated co-action among circuit simulators and finite element simulations to perform electrical, electromagnetic and thermal co-design, and finally an exclusion-based work flow with hierarchical computation to reduce computational load. The theorized framework is exemplified on designing a real world 175 ◦C 1.5kW Three-level Neutral-point-clamped dc-dc converter. A database containing the high-temperature characteristics of SiC MOSFETs and ferrites is established and shared through a web application with graphical user interface. In 310 min, the program, which includes computationally heavy 3D finite element simulation, delivers design output after evaluating the converter’s electrical, electromagnetic and thermal performance under 10 million parameter sets. Finally, a 1.5kW dc-dc converter prototype is built and tested in 175 ◦C ambient temperature to verify the quality of the design output.
KW - application programming interface
KW - component database
KW - design automation
KW - design methodology
KW - extreme temperature
U2 - 10.1109/OJPEL.2024.3439593
DO - 10.1109/OJPEL.2024.3439593
M3 - Article
SN - 2644-1314
VL - 5
SP - 1172
EP - 1181
JO - IEEE Open Journal of Power Electronics
JF - IEEE Open Journal of Power Electronics
ER -