Wang Qi

Biography：

Dr. Wang Qi is an Associate Professor and PhD Supervisor at Southeast University. He presides over 1 project of National Key R&D Program, 2 projects of National Natural Science Foundation of China, and 3 sub-projects of National Key R&D Program. In the past five years, he has published 42 journal papers as the first or corresponding author, including 21 papers indexed in SCI JCR Q1 and 10 papers in top domestic journals in the field. He has published 1 monograph and obtained 27 authorized national invention patents. His research achievements have won 1 First Prize of Science and Technology Progress Award of China Institute of Electronics, 1 First Prize of Invention and Entrepreneurship Innovation Award of China Invention Association, and 2 First Prizes of Electric Power Science and Technology Innovation Award of China Electricity Council. He has been selected into the "World's Top 2% Scientists List" for four consecutive years and the "CNKI Highly Cited Scholars TOP1%" for two consecutive years. He serves as an editorial board member/associate editor/young editorial board member of 8 domestic and foreign journals including IET Smart Grid and Electrical Measurement & Instrumentation, Secretary of IEEE PES Cyber-Physical Systems for Energy Internet Committee, and Director of Smart Grid Information Security Research Center of Southeast University.

Publications：       

Monographs

[1] Wang Q, Li F, Tang Y. Data and Knowledge Jointly Driven Methods and Their Applications in Power Systems[M]. Nanjing: Southeast University Press, 2023.

Journal Papers (First or Corresponding Author)

[1] S. Wu, Q. Wang, J. Hu, Y. Ye and Y. Tang. Dynamic PMU configuration for stealthy multi-snapshot fdia mitigation: enhancing security in hybrid-measurement-based state estimation in power systems[J]. IEEE Transactions on Smart Grid, 2026, 17(1):650-665. (IF=9.8, Corresponding Author)

[2] S. Wu, Q. Wang, J. Hu, Y. Ye and Y. Tang. Attack-resilient state estimation for cyber-physical power systems: A dynamic spatial-temporal redundancy reconfiguration framework for FDIA detection[J]. Applied Energy, 2025, 397:126330.(IF=10.2, Corresponding Author)

[3] J. Zhang, Q. Wang, J. Hu, S. Wu, Y. Ye and Y. Tang. Prior-knowledge-free data tampering on power system state estimation: a physics-constrained generative adversarial framework[J]. IEEE Internet of Things Journal, 2025. (IF=8.9, Corresponding Author)

[4] Y. Wang, Q. Wang, Y. Tang, Y. Xu and J. Hu. Online estimation of region inertia based on dynamic division with spatial-temporal perception[J]. IEEE Transactions on Power Systems, 2025. (IF=7.2, Corresponding Author)

[5] J. Hu, Q. Wang, Y. Ye and Y. Tang. High-resolution real-time power systems state estimation: a combined physics-embedded and data-driven perspective[J]. IEEE Transactions on Power Systems, 2025, 40(2):1532-1544. (IF=7.2, Corresponding Author)

[6] Y. Zhu, C. Miao, Q. Wang, Y. Ye and Y. Tang. A gas-thermal inertia-based ramping auxiliary service strategy of the integrated energy system. CSEE Journal of Power and Energy Systems, 2025. (IF=6.9, Corresponding Author)

[7] Q. Wang, J. Zhang, J. Hu, S. Wu, S. Hou and Y. Tang. A CGAN-based adversarial attack method for data-driven state estimation[J]. International Journal of Electrical Power & Energy Systems, 2025, 170:110878. (IF=5, First Author)

[8] S. Wu, Q. Wang, Q. Chen, C. Yu and Y. Tang. Cyber-physical integrated planning of distribution networks considering spatial-temporal flexible resources[J]. Protection and Control of Modern Power Systems, 2024, 9(3):142-156. (IF=8.7, Corresponding Author)

[9] Y. Liu, Y. Wang, H. Wang, and Q. Wang. Evaluating the optimal attack scheme of cross-domain cascading failures considering the spatiotemporal synergy relation of multiple attack-event-chains. CSEE Journal of Power and Energy Systems, 2026. (IF=6.9, Corresponding Author)

[10] J. Hu, Q. Wang, Y. Ye, Z. Wu and Y. Tang. A high temporal-spatial resolution power system state estimation method for online DSA[J]. IEEE Transactions on Power Systems, 2024, 39, (1):877-889. (IF=7.2, Corresponding Author)

[11] F. Li, Q. Wang, Y. Tang, Y. Xu and J. Dang. Hybrid analytical and data-driven model based instance-transfer method for power system online transient stability assessment[J]. CSEE Journal of Power and Energy Systems, 2024, 10(4):1664-1675. (IF=6.9, Corresponding Author)

[12] Q. Wang, S. Wu, Z. Wu, J. Hu, Q. He, Y. Ye and Y. Tang. Topology switching-based moving target defense against false data injection attacks on a power system [J]. International Journal of Electrical Power & Energy Systems, 2024, 163:110350. (IF=5, First Author)

[13] S. Wu, Q. Wang and C. Miao. Distribution network resilience enhancement strategy considering spatial‐temporal migration of flexible resources on supply and demand sides[J]. IET Renewable Power Generation, 2024, 18(7): 1177-1192. (IF=2.9, Corresponding Author)

[14] C. Miao, Q. Wang and Y. Tang. A gas-thermal inertia-based frequency response strategy considering the suppression of a second frequency dip in an integrated energy system[J]. Energy. 2023, 263:125880. (IF=9, Corresponding Author)

[15] C. Miao, Q. Wang and Y. Tang. A multi-energy inertia-based power support strategy with gas network constraints[J]. Protection and Control of Modern Power Systems, 2023, 8(2):1-18. (IF=8.7, Corresponding Author)

[16] J. Hu, Q. Wang, Y. Ye and Y. Tang. Toward online power system model identification: a deep reinforcement learning approach[J]. IEEE Transactions on Power Systems, 2023,38, (3):2580-2593. (IF=7.2, Corresponding Author)

[17] Q. Wang, C. Miao and Y. Tang. Power shortage support strategies considering unified gas-thermal inertia in an integrated energy system [J]. Applied Energy, 2022, 328:120229. (IF=10.2, First Author)

[18] W. Sun, Q. Wang, Y. Ye and Y. Tang. Unified modelling of gas and thermal inertia for integrated energy system and its application to multitype reserve procurement[J]. Applied Energy, 2022, 305:117963. (IF=10.2, Corresponding Author)

[19] Z. Liu, Q. Wang, Y. Ye and Y. Tang. A GAN-based data injection attack method on data-driven strategies in power systems[J]. IEEE Transactions on Smart Grid, 2022, 13(4):3203-3213. (IF=9.8, Corresponding Author)

[20] Z. Wu, Q. Wang, J. Hu, Y. Tang and Y. Zhang. Integrating model-driven and data-driven methods for fast state estimation [J]. International Journal of Electrical Power & Energy Systems, 2022, 139:107982. (IF=5, Corresponding Author)

[21] H. Wang, Q. Wang, Y. Tang and Y. Ye. Spatial load migration in a power system: Concept, potential and prospects[J]. International Journal of Electrical Power & Energy Systems, 2022, 140:107926. (IF=5, Corresponding Author)

[22] Q. Wang, Z. Liu and Y. Tang. SCCO: a state-caching-based coagulation platform for cyber-physical power system evaluation[J]. IEEE Transactions on Smart Grid, 2021, 12(2):1615-1625. (IF=9.8, First Author)

[23] Q. Wang, X. Cai, Y. Tang and M. Ni. Methods of cyber-attack identification for power systems based on bilateral cyber-physical information[J]. International Journal of Electrical Power & Energy Systems, 2021, 125:106515. (IF=5, First Author)

[24] F. Li, Q. Wang, Y. Tang and Y. Xu. An integrated method for critical clearing time prediction based on a model-driven and ensemble cost-sensitive data-driven scheme[J]. International Journal of Electrical Power & Energy Systems, 2021, 125:106513. (IF=5, Corresponding Author)

[25] N. Yi, Q. Wang, L. Yan, Y. Tang and J. Xu. A multi-stage game model for the false data injection attack from attacker’s perspective[J]. Sustainable Energy, Grids and Networks, 2021, 28:100541. (IF=4.8, Corresponding Author)

[26] Q. Wang, Z. Yu, J. Dai, Q. Yan, L. Fan and Y. Tang. Two-stage voltage control strategy for PV plants based on variable droop control[J]. International Journal of Electronics, 2020, 107(2):250-271. (IF=1.1, First Author)

[27] Q. Wang, F. Li, Y. Tang and Y. Xu. Integrating model-driven and data-driven methods for power system frequency stability assessment and control[J]. IEEE Transactions on Power Systems, 2019, 34(6):4557-4568. (IF=7.2, First Author)

[28] Q. Wang, W. Tai, Y. Tang, M. Ni and S. You. A two-layer game theoretical attack-defense model for a false data injection attack against power systems[J]. International Journal of Electrical Power & Energy Systems, 2019, 104:169-177. (IF=5, First Author)

[29] Q. Wang, C. Zhang, L. Y, Z. Yu and Y. Tang. Data inheritance–based updating method and its application in transient frequency prediction for a power system[J]. International Transactions on Electrical Energy Systems, 2019, 29(6):1-16. (IF=1.9, First Author)

[30] Q. Wang, W. Tai, Y. Tang and M. Ni. Review of the false data injection attack against the cyber-physical power system[J]. IET Cyber-Physical Systems: Theory & Applications, 2019, 4(2):101-107. (IF=1.7, First Author)

[31] Q. Wang, M. Pipattanasomporn, M. Kuzlu, Y. Tang, Y. Li and S. Rahman. Framework for vulnerability assessment of communication systems for electric power grids[J]. IET Generation, Transmission & Distribution, 2016, 10(2):477-486. (IF=2, First Author)

[32] S. Wu, Q. Wang, Y. Dong, J. Zhou, X. Zhang. Design of anti-attack function and security detection method for state estimation based on hybrid measurement spatiotemporal dynamic heterogeneity[J]. Proceedings of the CSEE, 2026. (EI, Corresponding Author)

[33] Q. Wang, J. Zhang, J. Hu, S. Wu, Y. Tang, Z. Wu. Review on functional safety of state estimation in cyber-physical power systems under cross-domain attack threats[J]. Automation of Electric Power Systems, 2026. (EI, First Author)

[34] Y. Dong, J. Zhou, X. Zhang, W. Liu, Q. Wang. Research on cyber-physical security protection system for new power systems[J]. Proceedings of the CSEE, 2025, 45(15):5738-5752. (EI, Corresponding Author)

[35] S. Wu, Q. Wang, C. Yu, Q. Hu, M. Song, Y. Tang. Cyber-physical integrated planning method for distribution networks considering spatiotemporal coordination of flexible resources[J]. Automation of Electric Power Systems, 2025, 49(15):74-88. (EI, Corresponding Author)

[36] T. Zhang, J. Fei, Q. Wang, Z. Shao, X. Cai. Research on coordinated defense architecture and mechanism against cross-domain attacks in cyber-physical power systems[J]. Acta Electronica Sinica, 2024, 52(4):1205-1218. (EI, Corresponding Author)

[37] H. Cui, T. Xue, Q. Wang, Y. Tang. Data poisoning backdoor attack method and detection scheme for artificial intelligence algorithms in power systems[J]. Power System Technology, 2024, 48(12):5024-5033. (EI, Corresponding Author)

[38] C. Yu, Q. Wang, S. Wu, Q. He. Collaborative optimal operation of 5G base stations and distribution networks considering spatiotemporal load migration[J]. Electric Power Automation Equipment, 2024, 44(12):195-203. (EI, Corresponding Author)

[39] Q. He, W. Liu, W. Yang, X. Wei, Q. Wang. Moving target defense strategy against load redistribution attacks[J]. Electric Power of China, 2024, 57 (09): 44-52. (Chinese Core, Corresponding Author)

[40] Z. Liu, Q. Wang, T. Xue, Y. Tang. Research on security threat analysis and countermeasures of data-driven algorithms in power systems[J]. Proceedings of the CSEE, 2023, 43(12):4538-4554. (EI, Corresponding Author)

[41] J. Chen, Q. Wang, Y. Tang, S. Bai. Anomaly detection method for cyber-physical power systems considering bilateral features[J]. Power System Technology, 2022, 46(6):2339-2348. (EI, Corresponding Author)

[42] S. Qian, Q. Wang, Y. Yan, K. Feng, H. Xia. Risk assessment method for security and stability control systems considering the impact of cyber attacks[J]. Electric Power Engineering Technology, 2022, 41(3):14-21. (Chinese Core, Corresponding Author)

[43] F. Li, Q. Wang, J. Hu, Y. Tang. Research progress of data and knowledge joint driving methods and their application prospects in power systems[J]. Proceedings of the CSEE, 2021, 41(13):4377-4390. (EI, Corresponding Author)

[44] W. Sun, Q. Wang, Y. Tang, M. Ding. Reserve configuration scheme for integrated energy systems considering gas-thermal inertia[J]. Automation of Electric Power Systems, 2021, 45(15):11-20. (EI, Corresponding Author)

[45] S. Tao, Q. Wang, Q. Zhao, Y. Li, Y. Tang. Load aggregation modeling and decentralized control method for frequency response under high power shortage[J]. Electric Power Automation Equipment, 2020, 40(2):182-188. (EI, Corresponding Author)

[46] X. Cai, Q. Wang, J. Huang, Z. Li. Cyber-physical two-layer coordinated emergency control method for cyber attacks in power systems[J]. Journal of Global Energy Interconnection, 2020, 3(6):560-568. (EI, Corresponding Author)

[47] Q. Wang, M. Li, Y. Tang, M. Ni. Review on cyber attack and defense in cyber-physical power systems (Part 1): Modeling and evaluation[J]. Automation of Electric Power Systems, 2019, 43(9):9-21. (EI, F5000 Top Academic Paper, First Author)

[48] Q. Wang, W. Tai, Y. Tang, M. Ni. Review on false data injection attacks against cyber-physical power systems[J]. Acta Automatica Sinica, 2019, 45(1):72-83. (EI, First Author)

[49] X. Cai, Q. Wang, W. Tai, K. Liu. Defense method against false data injection attacks in power CPS based on multi-stage game[J]. Electric Power Construction, 2019, 40(5):48-54. (Chinese Core, Corresponding Author)

[50] Q. Wang, F. Li, Y. Tang, Y. Xue. Online prediction method for transient frequency characteristics of power grids based on physics-data fusion model[J]. Automation of Electric Power Systems, 2018, 42(19):1-9. (EI, First Author)

[51] Y. Tang, F. Li, Q. Wang, M. Ni. Quantitative evaluation method for the impact of communication system faults on real-time load control of power systems[J]. Electric Power Automation Equipment, 2017, 37(2):90-96. (EI, Corresponding Author)

[52] Y. Tang, Q. Wang, W. Tai, B. Chen, M. Ni. Real-time simulation of cyber-physical power systems based on OPAL-RT and OPNET[J]. Automation of Electric Power Systems, 2016, 40(23):15-21+92. (EI, Corresponding Author)

[53] Y. Tang, Q. Wang, M. Ni, Y. Liang. Analysis of cyber attacks in cyber-physical power systems[J]. Automation of Electric Power Systems, 2016, 40(06):148-151. (EI, Corresponding Author)

[54] Y. Tang, Q. Wang, M. Ni, Y. Xue. Review on hybrid simulation methods for power and information communication systems[J]. Automation of Electric Power Systems, 2015, 39(23):33-42. (EI, Corresponding Author)

Journal Papers (Other Author)

[55] Z. Liu, M. Liu, Q. Wang and Y. Tang. False data injection attacks on data-driven algorithms in smart grids utilizing distributed power supplies[J]. Engineering, 2025, 51:62-74. (IF=11.6)

[56] M. Ni, M. Li, J. Li, Y. Wu and Q. Wang. Concept and research framework for coordinated situation awareness and active defense of cyber-physical power systems against cyber-attacks[J]. Journal of Modern Power Systems and Clean Energy, 2025, 9(3):477-484. (IF=6.1)

[57] G. Liu, C. Zhang, F. Li, X. Liu and Q. Wang. Delay-tolerant resilient model predictive control for load frequency stability in microgrids under hybrid cyber-physical attacks[J]. IEEE Transactions on Industry Applications, 2025, 3618789. (IF=4.5)

[58] L. Zhu, S. Wu, Q. Wang and Y. Li. Progressive identification of distribution network topology based on user‐side internet of things device measurement data[J]. IET Generation, Transmission and Distribution, 2025, 19(1). (IF=2.6)

[59] J. Hu, Y. Tang, F. Li, Q. Wang, X. Zhao. Performance analysis of parallel mode of data-physics fusion model in power systems[J]. Automation of Electric Power Systems, 2022, 46(1):15-24. (EI)

[60] Y. Tang, H. Cui, F. Li, Q. Wang. Review on applications of artificial intelligence in transient problems of power systems[J]. Proceedings of the CSEE, 2019, 39(1):2-13+315. (EI)

Authorized/Accepted National Invention Patents

[1] Wang Q, Zhang J, Hu J, Wu S, Hou S, Tang Y. A two-dimensional security risk assessment method for data-driven state estimation[P]. China: ZL119323357B, 2025-10-17.

[2] Wang Q, Wu S. A medium-voltage distribution network topology identification method considering regional similarity[P]. China: ZL115130327B, 2025-02-18.

[3] Wang Q, Miao C. A frequency modulation method for integrated energy systems considering gas-thermal inertia[P]. China: ZL114741988B, 2025-02-18.

[4] Wang Q, Miao C. A frequency modulation method considering flexible exit of thermal inertia in integrated energy systems[P]. China: ZL114741893B, 2025-02-18.

[5] Wang Q, Wu Z, He Q, Tang Y. A moving target defense method, device and storage medium based on reinforcement learning[P]. China: ZL115694904B, 2024-12-03.

[6] Sun W, Wang Q, Tang Y. An evaluation method and model for inertia characteristics of gas-thermal systems in integrated energy systems[P]. China: ZL113283107B, 2024-11-05.

[7] Sun W, Wang Q, Tang Y. An optimization method, system and device for integrated energy systems based on gas-thermal inertia[P]. China: ZL113298396B, 2024-06-18.

[8] Wang Q, Cai X, Tang Y. A method for generating white list of power operation status based on cyber-physical bilateral data[P]. China: ZL111950853B, 2024-05-31.

[9] Yuan Q, Tang Y, Wang Q, Ye Y. A weight quantification method for electric vehicle charging decision[P]. China: ZL112508364B, 2024-04-05.

[10] Wang Q, Wu S, Qian J, Zhou J. A low-voltage distribution network topology identification method based on IoT device measurement data[P]. China: ZL116317094B, 2024-03-19.

[11] Sun W, Wang Q, Tang Y. A two-stage multi-reserve configuration method, system and device based on gas-thermal inertia[P]. China: ZL113256009B, 2023-11-28.

[12] Wang Q, Miao C. An integrated energy inertia support method considering flexibility of combined heat and power units[P]. China: ZL114881416B, 2023-05-30.

[13] Wang Q, Liu Z, Tang Y. A joint simulation platform for cyber-physical power systems and its synchronization method[P]. China: ZL109977541B, 2023-03-31.

[14] Wang Q, Chen J, Tang Y. False data injection attack detection method and system based on state estimation residual distribution description[P]. China: ZL114666153B, 2022-11-18.

[15] Wang Q, He Q, Zhou J, Qian J. A moving target defense method based on flexible switching of backup lines[P]. China: ZL114978775B, 2022-11-18.

[16] Li F, Wang Q, Hu J, Tang Y, Duan F, Liu R. A DC transmission system equipment parameter identification method based on least square method[P]. China: ZL112949036B, 2022-11-08.

[17] Wang Q, Xue T, Tang Y. Backdoor attack impact assessment method, system and computer storage medium for data-driven algorithms in power systems[P]. China: ZL114726622B, 2022-11-01.

[18] Wang Q, Liu H, Tang Y, Qian J, Zhou J. A data center spatiotemporal transfer potential mining and evaluation method[P]. China: ZL114936240B, 2022-11-01.

[19] Wang Q, Liu H, Tang Y, Zhou J, Hao S. A day-ahead scheduling method based on spatiotemporal transfer characteristics of data centers[P]. China: ZL114936810B, 2022-10-18.

[20] Wang Q, Cai X, Tang Y. Cyber-physical two-layer strategy optimization method for power systems considering the impact of cyber attacks[P]. China: ZL111314387B, 2022-08-12.

[21] Sun W, Wang Q, Zhao A, Tang Y. A cyber security active defense resource allocation method and system[P]. China: ZL113395274B, 2022-07-05.

[22] Li F, Wang Q, Tang Y. A power grid critical clearing time prediction method based on EEAC and ELM[P]. China: ZL113067352B, 2022-07-05.

[23] Wang Q, Cai X, Tang Y. A sequence-data joint driven cyber attack identification method for distribution network CPS[P]. China: ZL111953657B, 2022-06-24.

[24] Wang Q, Tao S, Tang Y. A preventive-emergency control method for distribution networks containing multiple micro energy networks[P]. China: ZL110190630B, 2022-06-03.

[25] Wang Q, Wang H, Liu Z, Qi Z, Chen Y, Lei Y, Tang Y. A source-grid-load frequency response system[P]. China: ZL108667047B, 2022-04-05.

[26] Wang Q, Yuan Q, Tang Y. A dynamic modeling method for cyber-physical coupled power systems considering delay matrix[P]. China: ZL108509751B, 2022-02-15.

[27] Li F, Wang Q, Tang Y. A fast transient stability assessment method for power grids based on ELM and TF[P]. China: ZL108053128B, 2021-07-09.

[28] Wang Q, Cai X, Tai W, Tang Y. A two-layer defense method against false data injection attacks in power systems[P]. China: ZL107819785B, 2020-02-18.

[29] Wang Q, Xu Z, Tang Y, Li F. A quantitative analysis method for the impact of communication faults on real-time load control of power grids[P]. China: ZL105741028B, 2019-10-25.

[30] Wang Q, Tang Y, Li F. A power communication system joint simulation platform and its synchronization method based on variable time window synchronization mode[P]. China: ZL105740527B, 2019-05-31.

[31] Wang Q, Tang Y, Li F. A power communication joint simulation platform and its synchronization method with adaptive synchronization mode[P]. China: ZL105740528B, 2019-05-17.

[32] Tang Y, Li F, Wang Q, Chen B, Ni M. A power communication hybrid system simulation platform and simulation method[P]. China: ZL105184029B, 2018-06-26.

[33] Tang Y, Wang Q, Li F. A method for determining the action sequence of reactive power compensation devices in wind power systems[P]. China: ZL103489137B, 2016-08-31.

[34] Tang Y, Wang Q, Xie Y. Wind farm active power optimal control method based on power prediction information[P]. China: ZL102606395B, 2013-07-31.

Research：

[1] National Science and Technology Major Project, Ministry of Science and Technology, Key Technologies for Spatiotemporal Multi-domain Collaborative Security Attack and Defense of Power Grids, 2026～2029, 2.8 million CNY, Ongoing, Project Leader.

[2] National Natural Science Foundation of China (General Program), Key Technologies for Endogenous Security of Operation State Perception in New Power Systems under Cyber Attacks, 2025～2028, 0.48 million CNY, Ongoing, Project Leader.

[3] National Science and Technology Major Project, Ministry of Science and Technology, Key Technologies and Systems for Online Security and Stability Defense of Power Systems Facing Multi-dimensional Uncertainties, 2024～2028, 2.781 million CNY, Ongoing, Sub-project Leader.

[4] National Natural Science Foundation of China (Young Scientists Fund), Frequency Situation Prediction and Load Emergency Control Technology for Cyber-Physical Power Systems, 2018～2020, 0.22 million CNY, Completed, Project Leader.

[5] National Key R&D Program (China-International Science and Technology Innovation Cooperation Key Special Program), Ministry of Science and Technology, Key Technologies and Application Demonstration of Integrated Energy Efficient Collaborative Operation, 2021～2023, 0.6 million CNY, Completed, Sub-project Leader.

[6] National Key R&D Program, Ministry of Science and Technology, High-performance Analysis and Situation Awareness Technology for Interconnected Large Power Grids, 2018～2021, 1.67 million CNY, Completed, Sub-project Leader.

[7] National Natural Science Foundation of China (International Cooperation and Exchange Program), AI-based Smart Grid Analysis and Control Technology, 2023～2024, 2 million CNY, Completed, Sub-task Leader.

[8] National Key R&D Program, Ministry of Science and Technology, Basic Theories and Methods for Analysis and Control of Cyber-Physical Power Systems, 2017～2021, 2.142 million CNY, Completed, Sub-task Leader.

[9] Science and Technology Project of China Southern Power Grid Co., Ltd., Research on Cyber Security Risk Assessment Technology Based on Primary and Secondary Hybrid Simulation, 2024～2025, 3.69 million CNY, Completed, Project Leader.

[10] Science and Technology Project of State Grid Corporation of China Headquarters, Research on Key Technologies for Coordinated Defense against Cyber-Physical Attacks on Power Monitoring Systems, 2023～2025, Ongoing, Project Leader.

[11] Science and Technology Project of State Grid Corporation of China Headquarters, Research and Application of Online Inertia Monitoring and Evaluation Technology for New Power Systems, 2023～2024, Ongoing, Project Leader.

[12] Science and Technology Project of State Grid Corporation of China Headquarters, Research on Basic Technologies of Power Scientific Computing Based on Mechanism-Data-Knowledge Fusion, 2024～2025, Ongoing, Project Leader.

[13] Science and Technology Project of China Southern Power Grid Co., Ltd., Research on Key Technologies of Power Grid Information Security Protection Based on Device Fingerprint Identification, 2020～2021, Completed, Project Leader.

[14] Science and Technology Project of State Grid Corporation of China, Research on Key Technologies of Primary and Secondary Integration Planning for Distribution Networks Considering Cyber-Physical Uncertainties, 2021～2022, Completed, Project Leader.

[15] Science and Technology Project of State Grid Corporation of China, Research on Reliability and Risk Assessment Methods for Power Grid Control Systems from CPS Perspective, 2020～2021, Completed, Project Leader.

[16] Science and Technology Project of State Grid Corporation of China Headquarters, Key Technologies for Planning, Evaluation and Operation Strategy of Cyber-Physical Power Systems with Energy Integrated Service Stations as Hubs, 2020～2021, Completed, Project Leader.

[17] Science and Technology Project of State Grid Corporation of China Headquarters, Risk Analysis and Countermeasures of Power Grid Security and Stability Control Systems Subjected to Malicious Cyber Attacks, 2020～2021, Completed, Project Leader.

[18] Science and Technology Project of State Grid Corporation of China Headquarters, Research on Coordinated Operation Situation Awareness and Active Defense Methods for Cyber-Physical Power Systems Against Cyber Attacks, 2018～2020, Completed, Project Leader.

[19] Science and Technology Project of State Grid Corporation of China Headquarters, Research on Modeling and Digital-physical Hybrid Simulation Technology for Complex Distribution Networks Based on Cyber-Physical Systems, 2018～2020, Completed, Project Leader.

[20] Science and Technology Project of State Grid Corporation of China Headquarters, Research on Dispatching Strategies for Fast Demand Response to High Power Shortage, 2017～2019, Completed, Project Leader.

[21] Science and Technology Project of China Southern Power Grid Co., Ltd., Research on Cyber Security Assessment Technology for Cyber-Physical Power Systems, 2018～2019, Completed, Project Leader.

[22] Technology Foresight Project of State Grid Corporation of China, Research on Malicious Attack Modes of Source-Grid-Load Systems, 2018～2019, Completed, Project Leader.

[23] Science and Technology Project of State Grid Corporation of China Headquarters, Cyber-Physical Coupling Modeling and Evaluation for Power System Control Center Applications, 2017～2019, Completed, Project Leader.

Teaching：

Energy Internet Information Technology (School of Electrical Engineering / University-wide Elective, Autumn Semester)

Production Practice (School of Electrical Engineering, Short Semester)

Large Power Grid Technology (School of Electrical Engineering, Spring Semester)

Smart Grid (School of Electrical Engineering, Autumn Semester)

Power Information Technology (School of Electrical Engineering, Autumn Semester)

Control System Modeling and Simulation (School of Electrical Engineering, Spring Semester)

MATLAB Application and Practice (School of Electrical Engineering, Short Semester)

Graduates：

PhD Students

2017: Li Feng (Graduated in 2021, Nanjing Normal University)

2018: Liu Zengji (Graduated in 2022, Nanjing Normal University)

2021: Hu Jianxiong (Graduated in 2024, Wenzhou University), Wang Hongru (Graduated in 2024, Hohai University)

2023: Wang Yalun

2024: Wu Shutan, Tai Wei

2024: Zhang Ziyi

Master Students

2016: Tai Wei, Li Mengya (National Scholarship), Liu Zengji, Cui Han

2017: Tao Sumeng (National Scholarship), Sun Dasong, Yu Zhipeng, Zhang Chaoming

2018: Cai Xingpu (National Scholarship), Wang Hongru, Hu Jianxiong

2019: Sun Weijia (National Scholarship), Chen Jiaqi, Qian Sheng

2020: Liu Haoyu, Wu Zhong, Xue Tong, Wu Zhaoyu

2021: Wu Shutan (National Scholarship), Miao Cairan (National Scholarship), Xia Yuxiang, Ma Yucheng

2022: Zhang Ziyi, He Quanpeng, Yu Changping, Li Yinuo

2023: Zhang Jing (National Scholarship), Song Jiawen

2024: Li Xin, Hou Shiyi

2025: Zhu Rongjia, Lou Mingqi

2026: Liu Haoyu, Yin Jiamei, Lin Meng