第二届电力电子化电力系统运行与控制国际暑期学校
活动概述:
●主题:第二届电力电子化电力系统运行与控制国际暑期学校
●时间:2025年8月25日-9月2日(7天课程+2天技术考察)
●地点:北京 · 清华大学
●主办方:清华大学电机系、英国帝国理工学院控制与电力研究组
●支持机构:清华-帝国理工智能电力与能源系统联合研究中心(JCIPES)、零碳电力创新中心(EPICS)
背景与目标:
全球能源转型正加速推动电力系统向以电力电子装备为主导的结构形态转变,这一变革对电力系统的建模、控制、运行、规划及市场提出了前所未有的挑战。由清华大学与帝国理工学院联合主办的第二届国际暑期学校,聚焦电力电子化电力系统的前沿议题,旨在为全球电力工程领域的青年学者、学生及行业从业者提供系统性培训与创新实践平台。
项目亮点:
1.顶尖师资团队:30余位来自清华大学、帝国理工学院、剑桥大学、北京大学、瑞典皇家理工学院(KTH)、浙江大学、中国电力科学研究院、中国矿业大学、约翰霍普金斯大学、莫纳什大学、雅典国立技术大学(NTUA)、首尔国立大学、上海交通大学、墨尔本大学、德州大学奥斯汀分校、天津大学、思克莱德大学等全球知名高校与机构的专家授课。
2.产学研深度融合:参访企业实验室、工业制造基地及新能源基地,实地考察技术应用。
3.文化体验:融入中国传统文化活动,体验中国文化历史的博大精深。
4.全球学术网络:与来自欧洲、美洲、亚洲及澳洲的100名优秀学生及行业专家交流合作。
报名信息:
●费用:
1,¥6000(7天课程)
2,¥7500(7天课程+2天技术考察)
●招生对象:电力工程、能源系统及相关领域的硕士/博士生、青年学者及行业从业者。
●招生规模:100人(申请制,择优录取)。
●申请截止:2025年5月25日。
●申请方式:
●签证支持:
●住宿:
2nd International Summer School on IBR-dominated Power Systems
25 August—2 September 2025
Background and Objectives
The global energy transition is accelerating the shift towards power systems dominated by Inverter-Based Resources (IBRs), posing unprecedented challenges in modeling, control, operation, and planning. This International Summer School, hosted by Tsinghua and Imperial, brings together world-leading experts to provide unique training for research students and indutry practioners with a holisic coverage over the modelling, control, stability, optimisation, market and investment for IBR-dominated power systems.
Core Topics
This summer school aims to provide a holistic view of these challenges and identify the emerging research directions for future IBR-dominated power systems. More specifically, the summer school covers the following topics:
Modelling and Control of Power Converters
System Stability Definition and Analysis Methods
Novel Protection Solutions
Development of Monitoring and Simulation Techniques
Assessment of System Security, Reliability and Resilience
Power System Operation and Planning
Service Market Design and Economic Analysis
Organisers
Department of Electrical Engineering, Tsinghua University (contact Dr. Ning Zhang)
Control and Power Group, Imperial College London (contact Dr. Fei Teng)
Supporting Organisation:
Tsinghua-Imperial Joint Research Center on Intelligent Power and Energy Systems (JCIPES)
Electric Power Innovation for a Carbon-free Society Centre (EPICS)
The Department of Electrical Engineering at Tsinghua University is a leading academic institution with a significant global impact. The department has over 100 full-time professors and researchers, pioneering advancements in smart grids, renewable integration, and high-voltage transmission, and power system automation. The Control and Power Group at Imperial College London has 20 academic members and is a prominent division within the Department of Electrical and Electronic Engineering. The group is dedicated to advancing the fields of control systems and power engineering through innovative research and education. Renowned for its cutting-edge work, the group focuses on addressing the challenges posed by modern control systems and the integration of renewable energy sources into the power grid. In recent years, the group has developed world-leading research portfolios in IBR-dominated Power Systems.
JCIPES is a collaboration between Tsinghua University and Imperial College London, focuses on tackling common challenges faced by the UK and China in providing secure, low-carbon power systems. The center brings together academics from several departments, focuses on whole-system analysis of low-carbon energy infrastructures, flexible distributed energy resources, AC/DC technologies in micro-grids and mega-grid, data driven control, power system resilience, interactions between heat, gas, transport, electricity and water systems, cyber security technology, policy, business and market models decarbonized energy systems.
EPICS-UK is a collaboration between Department of Electrical and Electronic Engineering at Imperial College London, the Business School and Dyson School of Design Engineering with the Department of Electronic & Electrical Engineering at the University of Strathclyde and the School of Social and Political Science at the University of Edinburgh. It is a part of the EPICS Global Centre, collaborating with academic leaders from Australia (University of Melbourne, Monash University, Commonwealth Scientific and Industrial Research Organization) and the United States (Johns Hopkins University, Georgia Tech, University of California Davis and Resources for the Future). EPICS is dedicated to pioneering scientific principles and developing cutting-edge tools to realise a power grid with 100% renewable energy. EPICS stands as a global multidisciplinary cradle-to-grave innovation and implementation ecosystem, engaging stakeholders from academia and industry, ensuring a rapid and effective response to the pressing challenges faced by the transforming power grids.
Highlights
●World-class teaching team: 30+ experts from Tsinghua University, Imperial College London, Cambridge University, Peking University,KTH Royal Institute of Technology, Zhejiang University, China Electric Power Research Institute, China University of Mining and Technology, Johns Hopkins University, Monash University, National Technical University of Athens, Seoul National University, Shanghai Jiao Tong University, The University of Melbourne, The University of Texas at Austin, Tianjin University, and University of Strathclyde.
●Industry-academia integration: site visits to corporate laboratories, industrial manufacturers, and renewables energy complexes.
●Cultural immersion: Experience Chinese culture and history
●Global network: Collaborate with 100 outstanding students and industry experts from Europe, the Americas, Asia, and Australia.
Schedule
Dates: August 25 – September 2, 2025 (7 days technical sessions plus 2 days technical tour)
Venue: Tsinghua University, Haidian, Beijing, China
Fees:
1.¥6000-Academic participation fee for 7 days
2.¥7500-Academic participation fee for 7 days and technical tour for extra 2 days
Admission
●Target participants: Master’s/PhD students, early-career researchers, and industry professionals in power engineering, energy systems, or related fields.
●Capacity: 100 seats (competitive selection).
●Application due: 11 May,2025
Contact:
●Email: Jindan Zhang: opairs@tsinghua.edu.cn,Jia Zhang: zhangjia@tsinghua-eiri.org
●Application website: https://imperial.eu.qualtrics.com/jfe/form/SV_9Fa0jaOT20muirQ
Only complete and successfully submitted applications will undergo evaluation.
●Visa:
●Accommodation:
On-Campus Accommodation (allocated based on application sequence)
▸ Double Room: ¥40 RMB/person/night
▸ Triple Room: ¥30 RMB/person/night
Facilities include: Air conditioning, study desk, storage cabinet, and shared bathroom facilities.
Off-Campus Accommodation
▸ Surrounding Hotels: Approximately ¥500/night
Note: Reservations must be independently arranged by participants, and pricing is subject to actual hotel rates
Lecturer and Title
Lecturer |
Title |
Mark O'Malley, Imperial College London |
Service and market for IBR-dominated power systems |
Mahmoud Fotuhi-Firuzabad, Sharif University of Technology |
Reliability Evaluation of Bulk Power Systems with Renewable Resources |
Goran Strbac, Imperial College London |
Co-optimisation of Energy and Frequency-containment Services in GB Power System |
Xiaorong Xie, Tsinghua University |
Power Oscillation analysis and control |
Balarko Chaudhuri, Imperial College London |
IBR-driven Sub-synchronous Oscillation |
Xiongfei Wang, KTH Royal Institute of Technology |
Exploring Functional Specifications of Grid-Forming Converters |
Ross Baldick, The University of Texas at Austin |
An Increased Role for the Demand Side in Renewable Integration |
Pierluigi Mancarella, The University of Melbourne |
Economics, markets and regulation for new essential system services: first principles and practical experiences |
Nikos Hatziargyriou, NTUA |
Definition and Classification of Power System Stability–Revisited & Extended |
Ning Zhang, Tsinghua University |
Data-driven Stability Rule Extraction in IBR-dominated Power Systems |
Fei Teng, Imperial College London |
Stability-constrained Optimization for IBR-dominated Power Systems |
Giordano Scarciotti, Imperial College London |
Model reduction for IBR-dominated Power Systems |
Michael Pollitt, University of Cambridge |
Modelling flexibility requirements in deep decarbonisation scenarios: The role of conventional flexibility and sector coupling options in the European 2050 energy system |
Ioannis Lestas, University of Cambridge |
Decentralised Stability Analysis of IBR-dominated Power Systems |
Sijia Geng, Johns Hopkins University |
Resilience of IBR-dominated Power Systems |
Qiteng Hong, University of Strathclyde |
Protection of Power Systems with High Penetration of IBRs |
Behrooz Bahrani, Monash University |
Small Signal and Large Signal Stability in Grid-Forming Inverters |
Gyu-Sub Lee, Seoul National University |
Power system strength and its optimization to accommodate high-penetration of IBRs |
Shenghui Cui, Seoul National University |
Control and Power Hardware-in-the-Loop |
Linbin Huang, Zhejiang University |
Power system formulation and staiblity analysis with data-driven control |
Shiyun Xu, China Electric Power Research Institude |
Secure and Stable Operation of Chinese Bulk Power Grid with high penetration of renewable energies |
Zhongda Chu , Tianjin University |
Power system operation and planning considering IBR |
Chen Shen, Tsinghua University |
Power system control and simulation |
Hong Li, Zhejiang University |
Electromagnetic compatibility and stability of power electronic systems |
Lei Chen, Tsinghua University |
Power system dynamic analysis and control |
Miao Zhu, Shanghai Jiaotong University |
DC distribution network and flexible DC transmission |
Mingyang Sun, Peking University |
Exploring Smart Grid Vulnerability Against Intelligent Inverter Parameter Tampering Attack |
Xiaoqian Li, Tsinghua University |
Modular multilevel converter HVDC |
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