Wide-area metering topology modeling and fusion optimization of distributed power trending algorithms in dynamic power networks

[1] Siyu, C., Hang, S., Yiqun, W., Lingyi, T., Xiaojing, S., & Fengzhu, H. (2024, February). Design and research of power grid data transmission system based on LoRa technology. In 2024 IEEE 3rd International Conference on Electrical Engineering, Big Data and Algorithms (EEBDA) (pp. 1524-1528). IEEE. SiyuC.HangS.YiqunW.LingyiT.XiaojingS. & FengzhuH. (2024, February). Design and research of power grid data transmission system based on LoRa technology. In 2024 IEEE 3rd International Conference on Electrical Engineering, Big Data and Algorithms (EEBDA) (pp. 1524-1528). IEEE.Search in Google Scholar

[2] Rahman, M. A., Kim, J. H., & Hossain, S. (2022). Recent advances of energy storage technologies for grid: A comprehensive review. Energy Storage, 4(6), e322. RahmanM. A.KimJ. H. & HossainS. (2022). Recent advances of energy storage technologies for grid: A comprehensive review. Energy Storage, 4(6), e322.Search in Google Scholar

[3] Denis, G., Prevost, T., Debry, M. S., Xavier, F., Guillaud, X., & Menze, A. (2018). The Migrate project: the challenges of operating a transmission grid with only inverter‐based generation. A grid‐forming control improvement with transient current‐limiting control. IET Renewable Power Generation (Wiley-Blackwell), 12(5). DenisG.PrevostT.DebryM. S.XavierF.GuillaudX. & MenzeA. (2018). The Migrate project: the challenges of operating a transmission grid with only inverter‐based generation. A grid‐forming control improvement with transient current‐limiting control. IET Renewable Power Generation (Wiley-Blackwell), 12(5).Search in Google Scholar

[4] Liu, M., Dassios, I., Tzounas, G., & Milano, F. (2019). Stability Analysis of Power Systems With Inclusion of Realistic-Modeling WAMS Delays. IEEE Transactions on Power Systems, 34(1), 627-636. LiuM.DassiosI.TzounasG. & MilanoF. (2019). Stability Analysis of Power Systems With Inclusion of Realistic-Modeling WAMS Delays. IEEE Transactions on Power Systems, 34(1), 627-636.Search in Google Scholar

[5] Vittal, V., McCalley, J. D., Anderson, P. M., & Fouad, A. A. (2019). Power system control and stability. John Wiley & Sons. VittalV.McCalleyJ. D.AndersonP. M. & FouadA. A. (2019). Power system control and stability. John Wiley & Sons.Search in Google Scholar

[6] Avalos, A., Zamora, A., Escamilla, O., & Paternina, M. R. A. (2018, September). Real-time hardware-in-the-loop implementation for power systems protection. In 2018 IEEE PES Transmission & Distribution Conference and Exhibition-Latin America (T&D-LA) (pp. 1-5). IEEE. AvalosA.ZamoraA.EscamillaO. & PaterninaM. R. A. (2018, September). Real-time hardware-in-the-loop implementation for power systems protection. In 2018 IEEE PES Transmission & Distribution Conference and Exhibition-Latin America (T&D-LA) (pp. 1-5). IEEE.Search in Google Scholar

[7] Khalid, H. M., Qasaymeh, M. M., Muyeen, S. M., Moursi, M. S. E., Foley, A. M., Sweidan, T. E. O., & Sanjeevikumar, P. (2023). WAMS Operations in Power Grids: A Track Fusion-Based Mixture Density Estimation-Driven Grid Resilient Approach Toward Cyberattacks. IEEE Systems Journal, 17(3), 3950-3961. KhalidH. M.QasaymehM. M.MuyeenS. M.MoursiM. S. E.FoleyA. M.SweidanT. E. O. & SanjeevikumarP. (2023). WAMS Operations in Power Grids: A Track Fusion-Based Mixture Density Estimation-Driven Grid Resilient Approach Toward Cyberattacks. IEEE Systems Journal, 17(3), 3950-3961.Search in Google Scholar

[8] PHADKE, A. G., & BI, T. (2018). Phasor measurement units, WAMS, and their applications in protection and control of power systems. Journal of Modern Power Systems and Clean Energy, 6, 619-629. PHADKEA. G. & BIT. (2018). Phasor measurement units, WAMS, and their applications in protection and control of power systems. Journal of Modern Power Systems and Clean Energy, 6, 619-629.Search in Google Scholar

[9] Kateb, R., Akaber, P., Tushar, M. H., Albarakati, A., Debbabi, M., & Assi, C. (2018). Enhancing WAMS communication network against delay attacks. IEEE Transactions on Smart Grid, 10(3), 2738-2751. KatebR.AkaberP.TusharM. H.AlbarakatiA.DebbabiM. & AssiC. (2018). Enhancing WAMS communication network against delay attacks. IEEE Transactions on Smart Grid, 10(3), 2738-2751.Search in Google Scholar

[10] Li, Y., Shi, F., & Zhang, H. (2018, May). Panoramic synchronous measurement system for wide-area power system based on the cloud computing. In 2018 13th IEEE Conference on Industrial Electronics and Applications (ICIEA) (pp. 764-768). IEEE. LiY.ShiF. & ZhangH. (2018, May). Panoramic synchronous measurement system for wide-area power system based on the cloud computing. In 2018 13th IEEE Conference on Industrial Electronics and Applications (ICIEA) (pp. 764-768). IEEE.Search in Google Scholar

[11] Cetina, R. Q., Roscoe, A. J., & Wright, P. S. (2017, August). A review of electrical metering accuracy standards in the context of dynamic power quality conditions of the grid. In 52nd International Universities’ Power Engineering Conference. IEEE. CetinaR. Q.RoscoeA. J. & WrightP. S. (2017, August). A review of electrical metering accuracy standards in the context of dynamic power quality conditions of the grid. In 52nd International Universities’ Power Engineering Conference. IEEE.Search in Google Scholar

[12] Li, Y., Fan, L., & Miao, Z. (2020). Wind in Weak Grids: Low-Frequency Oscillations, Subsynchronous Oscillations, and Torsional Interactions. IEEE Transactions on Power Systems, 35(1), 109-118. LiY.FanL. & MiaoZ. (2020). Wind in Weak Grids: Low-Frequency Oscillations, Subsynchronous Oscillations, and Torsional Interactions. IEEE Transactions on Power Systems, 35(1), 109-118.Search in Google Scholar

[13] Farmer, W. J., & Rix, A. J. (2021). The Network Topology Metrics Contributing to Local-Area Frequency Stability in Power System Networks. Energies, 14(15), 1-28. FarmerW. J. & RixA. J. (2021). The Network Topology Metrics Contributing to Local-Area Frequency Stability in Power System Networks. Energies, 14(15), 1-28.Search in Google Scholar

[14] Fu, L. (2022, October). An Analysis of Influence of Network Topology on Power Network Reliability Based on OPLC. In Journal of Physics: Conference Series (Vol. 2358, No. 1, p. 012011). IOP Publishing. FuL. (2022, October). An Analysis of Influence of Network Topology on Power Network Reliability Based on OPLC. In Journal of Physics: Conference Series (Vol. 2358, No. 1, p. 012011). IOP Publishing.Search in Google Scholar

[15] Srivastava, A., Chakrabarti, S., Soares, J., & Singh, S. N. (2022). An optimization-based topology error detection method for power system state estimation. Electric Power Systems Research, 209, 107914. SrivastavaA.ChakrabartiS.SoaresJ. & SinghS. N. (2022). An optimization-based topology error detection method for power system state estimation. Electric Power Systems Research, 209, 107914.Search in Google Scholar

[16] Cavraro, G., Bernstein, A., Kekatos, V., & Zhang, Y. (2019). Real-Time Identifiability of Power Distribution Network Topologies With Limited Monitoring. IEEE Control Systems Letters, 4(NREL/JA-5D00-73447). CavraroG.BernsteinA.KekatosV. & ZhangY. (2019). Real-Time Identifiability of Power Distribution Network Topologies With Limited Monitoring. IEEE Control Systems Letters, 4(NREL/JA-5D00-73447).Search in Google Scholar

[17] Meinecke, S., Sarajlić, D., Drauz, S. R., Klettke, A., Lauven, L. P., Rehtanz, C., ... & Braun, M. (2020). SimBench—A Benchmark Dataset of Electric Power Systems to Compare Innovative Solutions Based on Power Flow Analysis. Energies, 13(12), 1-19. MeineckeS.SarajlićD.DrauzS. R.KlettkeA.LauvenL. P.RehtanzC. ... & BraunM. (2020). SimBench—A Benchmark Dataset of Electric Power Systems to Compare Innovative Solutions Based on Power Flow Analysis. Energies, 13(12), 1-19.Search in Google Scholar

[18] Li, Z., Yu, J., & Wu, Q. H. (2018). Approximate Linear Power Flow Using Logarithmic Transform of Voltage Magnitudes With Reactive Power and Transmission Loss Consideration. IEEE Transactions on Power Systems, 33(4), 4593-4603. LiZ.YuJ. & WuQ. H. (2018). Approximate Linear Power Flow Using Logarithmic Transform of Voltage Magnitudes With Reactive Power and Transmission Loss Consideration. IEEE Transactions on Power Systems, 33(4), 4593-4603.Search in Google Scholar

[19] Ehsan, A., & Yang, Q. (2018). Optimal integration and planning of renewable distributed generation in the power distribution networks: A review of analytical techniques. Applied Energy, 210(C), 44-59. EhsanA. & YangQ. (2018). Optimal integration and planning of renewable distributed generation in the power distribution networks: A review of analytical techniques. Applied Energy, 210(C), 44-59.Search in Google Scholar

[20] Bansal, R. (Ed.). (2017). Handbook of Distributed Generation: Electric Power Technologies, Economics and Environmental Impacts. Springer. BansalR. (Ed.). (2017). Handbook of Distributed Generation: Electric Power Technologies, Economics and Environmental Impacts. Springer.Search in Google Scholar

[21] Emile Emery,Hervé Bercegol,Nicolas Jonqueres & Sébastien Aumaître. (2024). Complex network analysis of transmission networks preparing for the energy transition: application to the current French power grid. The European Physical Journal B(12),201-201. EmeryEmileBercegolHervéJonqueresNicolas & AumaîtreSébastien. (2024). Complex network analysis of transmission networks preparing for the energy transition: application to the current French power grid. The European Physical Journal B(12),201-201.Search in Google Scholar

[22] Li Yifan,Wang Bo,Wang Hongxia,Ma Fuqi,Ma Hengrui,Zhang Jiaxin... & Mohamed Mohamed A. (2022). An Effective Node-To-Edge Interdependent Network and Vulnerability Analysis for Digital Coupled Power Grids. International Transactions on Electrical Energy Systems. YifanLiBoWangHongxiaWangFuqiMaHengruiMaJiaxinZhang... & Mohamed Mohamed A. (2022). An Effective Node-To-Edge Interdependent Network and Vulnerability Analysis for Digital Coupled Power Grids. International Transactions on Electrical Energy Systems.Search in Google Scholar

[23] Fang Yuchen,Tang Xiafei,Tang Li,Chen Yang & Wang Weiyu. (2022). Local Evolution Model of the Communication Network for Reducing Outage Risk of Power Cyber-Physical System. Energies(21), 7876-7876. YuchenFangXiafeiTangLiTangYangChen & WeiyuWang. (2022). Local Evolution Model of the Communication Network for Reducing Outage Risk of Power Cyber-Physical System. Energies(21), 7876-7876.Search in Google Scholar

[24] Lin Ye,Yali Zhang,Cihang Zhang,Peng Lu,Yongning Zhao & Boyu He. (2019). Combined Gaussian Mixture Model and cumulants for probabilistic power flow calculation of integrated wind power network. Computers and Electrical Engineering117-129. YeLinZhangYaliZhangCihangLuPengZhaoYongning & HeBoyu. (2019). Combined Gaussian Mixture Model and cumulants for probabilistic power flow calculation of integrated wind power network. Computers and Electrical Engineering117-129.Search in Google Scholar