Enabling Technologies and Applications for Power Electronics-Enabled Electric Power Distribution Systems

Dr. Wencong Su is an Associate Professor in the Department of Electrical and Computer Engineering at the University of Michigan-Dearborn. He received his B.S. degree (with distinction) from Clarkson University, Potsdam, NY, USA, in May 2008, his M.S. degree from Virginia Tech, Blacksburg, VA, USA, in December 2009, and his Ph.D. degree from North Carolina State University, Raleigh, NC, USA, in August 2013, respectively, all in electrical engineering. He is a registered Professional Engineer (P.E.) in the State of Michigan. He is an Editor of IEEE Transactions of Smart Grid and an Associate Editor of IEEE Access. Dr. Su is a Fellow of IET (Institution of Engineering and Technology) and a Senior Member of IEEE (Institute of Electrical and Electronics Engineers). He has authored 1 book, 4 book chapters, and over 100 high-quality articles in prestigious international journals and peer-reviewed conference proceedings. He serves as the campus director of Center for Electric Drive Transportation (2015-present) and NSF REU Site (2018-present) at the University of Michigan-Dearborn. He also serves as an associate director of Dearborn Artificial Intelligence Research Center. His current research interests include power systems, electrified transportation systems, machine learning applications, and cyber-physical systems. Dr. Alex Huang is the Dula D. Cockrell Centennial Chair in Engineering at the Department of Electrical and Computer Engineering at UT Austin. Dr. Huang received the bachelor's degree in electrical engineering from Zhejiang University, China in 1983 and his M.S. degree from University of Electronic Science and Technology of China in 1986. He received his Ph.D. in electrical engineering from University of Cambridge, UK in 1992. Prior to joining UT Austin, Dr. Huang has been a faculty member at Virginia Tech (1994-2004) and NC State University (2004-2017). At NC State, Dr. Huang has established a number of internationally renowned public-private partnerships such as the NSF FREEDM ERC in 2008, NCSU's Advanced Transportation Energy Center (ATEC) in 2008 and the DOE PowerAmerica Institute in 2014. Dr. Huang is a world-renowned expert of power semiconductor devices, power electronics, smart grid and renewable energy system. He has published more than 550 papers in journals and conferences and is the inventor of more than 20 US patents including several patents on the Emitter turn-off (ETO) thyristor technology that received a prestigious R&D 100 award in 2003. Dr. Huang is also widely credited for his contribution in developing the Energy Internet concept and the Solid State Transformer (SST) based Energy Router technology. His work on the SST has been named by MIT Technology Review as one of the world’s 10 most important emerging technologies in 2011. He has graduated more than 80 Ph.D. students and master students. Dr. Huang is a fellow of IEEE and the general chair of IEEE ECCE Conference in 2012. He is also a fellow of the National Academy of Inventors. Dr. Huang is the recipient of 2019 IEEE IAS Gerald Kliman Innovator Award.

Section 1. Overview and Vision
1.1 The need and challenges of power electronics-enabled electric power distribution systems: From power systems perspectives
UM-Dearborn
1.2 The need and challenges of power electronics-enabled electric power distribution systems: From power electronics perspectives
UT-Austin

Section 2. Stability and Reliability of Modern Microgrid
2.1 Large-signal stability analysis of DC microgrid systems based on potential theory
UM-Dearborn
2.2 Large-signal stability visualization and enhancement of DC grid
UM-Dearborn
2.3 Digital control technologies for DC-DC converters in microgrids
UM-Dearborn
2.4 Machine-Learning-assisted reliability analysis of power systems integrated with high-penetration of power converters
UM-Dearborn
2.5 Stability and control of weak AC systems
UM-Dearborn
2.6 The roles of retail demand response for ancillary services in microgrids
UM-Dearborn

Section 3. Grid Forming Synchronous Generators for Active Distribution Systems with High Penetration of Distributed Renewable Generation
3.1 From grid-following to grid-forming inverters: a paradigm shift
UM-Dearborn & UT-Austin
3.2 Grid-forming photovoltaic inverter
UT-Austin

Section 4. Solid State Technology for Active Distribution Systems with High Penetration of Distributed Renewable Generation
4.1 Overview of solid-state technology in grid-scale applications
UT-Austin
4.2 Solid state transformer (SST)
UT-Austin
4.3 Solid state circuit breaker (SSCB) and fault isolation device (FID)
UT-Austin