Team Leader
Lu Chao, Tenure Associate Professor, PhD Supervisor, Assistant Dean, Young Yangtze River Scholar, specializing in intelligent grid state perception and control, wide-area measurement systems, and artificial intelligence technology applications
luchao@tsinghua.edu.cn
Key Team Members
Han Yingduo, Professor, PhD Supervisor, Member of Chinese Academy of Engineering, specializing in state perception and analysis control of complex power systems, high-power power electronics technology, and flexible DC transmission and distribution technology
hanyd@tsinghua.edu.cn
Xie Xiaorong, Tenure Professor, PhD Supervisor, IET Fellow, recipient of the Distinguished Youth Fund, specializing in wide-band oscillation analysis and control of next-generation energy power systems
xiexr@tsinghua.edu.cn
Liu Wenhua, Researcher, PhD Supervisor, specializing in high-power power electronics technology and flexible DC transmission and distribution technology
liuwenh@tsinghua.edu.cn
Song Qiang, Tenure Associate Professor, PhD Supervisor, specializing in flexible DC transmission, DC grids, and novel high-efficiency power conversion technology
songqiang@tsinghua.edu.cn
Yuan Zhichang, Associate Professor, specializing in flexible DC transmission and distribution technology
yuanzc@tsinghua.edu.cn
Yu Qingguang, Associate Professor, specializing in control technology for microgrids and energy storage systems
qinggy@tsinghua.edu.cn
Wei Yingdong, Associate Researcher, specializing in electrified railway traction power supply technology and flexible DC distribution network control technology
wyd@tsinghua.edu.cn
Zhang Shuqing, Assistant Researcher, specializing in multi-layer integration of AC/DC power grids and multi-scale hybrid simulation technology
zsq@tsinghua.edu.cn
Li Xiaoqian, Assistant Researcher, specializing in flexible DC transmission and DC grid technology
lixq-dee@tsinghua.edu.cn
Team Research Directions
The team focuses on the next-generation AC/DC interconnected power grid, which leverages advanced technologies such as wide-area information, state perception, and power electronics to greatly enhance its safety, stability, efficiency, and intelligence. State perception, control, and key equipment development are core technologies, divided into three main research directions:
1. Next-generation power system state perception and control technology: Addressing key stability issues and novel stability issues in flexible interconnected power grids, achieving real-time state perception and intelligent control based on the latest information, communication, and control technologies. Focus areas include: flexible grid basic information and comprehensive security state perception technology based on large-scale measured data, intelligent scheduling technology based on deep learning, and flexible interconnected power system sub-synchronous oscillation analysis and control technology.
2. Flexible DC transmission and DC grid technology: Including new large-capacity flexible DC converter technology, high-efficiency compact flexible DC access technology for large-scale renewable energy, new high-frequency link power conversion technology, and DC solid-state transformer technology, as well as energy interconnection and control technology based on flexible DC.
3. Multi-layer fusion of AC/DC power grids - Multi-scale hybrid simulation technology: Including multi-layer fusion of AC/DC interconnected power grids, multi-time scale hybrid real-time simulation technology, and operational deduction and fine characteristic simulation technology for flexible power grids and energy interconnection microgrids.