Feng Huang, Rui Wang, Yuelin Yu, Feiyu Hu, Xin Xie, and Lingxiang Huang
[1] Y. Wang, Analysis of the current situation and developmenttrend of wind power generation, Electric Power EquipmentManagement, 11, 2020, 21–22. [2] Xu Mengtian, Wang Hongzhe, Zhao Chengping, Yan Hua,Research on data preprocessing policy based on short-termwind power prediction, Renewable Energy Resources, 37(01),2019, 119–125. [3] C. Ma, Research on development status of wind power energyand its grid-connected technology, Hunan Hydro & Power, 2,2020, 65–69. [4] S. Wang and D. Xie, A simple analysis of the impact of grid-connected wind power on power quality, Electronic Technology& Software Engineering, 23, 2018, 220–221. [5] M. Moradi, Y. Weng, and Y.C. Lai, Defending smart electricalpower grids against cyberattacks with deep Q-learning, P RX Energy, 1, 2022, 033005. [6] Maheswari Chenniappan, Divya Gnanavel, Kavi PriyaGunasekaran, R.R. Rajalakshmi, A.S Ramya, Albert AlexanderStonier, Geno Peter and Vivekananda Ganji, Prediction offault occurrences in smart city water distribution system usingtime-series forecasting algorithm, Mathematical Problems inEngineering, 2022, 2022, 9678769. [7] L. Changro and P. Keith Key-Ho, Forecasting trading volumein local housing markets through a time-series model and a deeplearning algorithm, Engineering Construction and ArchitecturalManagement, 29(1), 2022, 165–178. [8] Zhang Xiaojie, Cai Wenchuan, Gan Zhongxue, Coordinatedcontrol strategy for active power of wind power cluster basedon model, predictive control, Proceedings of the CSEE, 41(17),2021, 5887–5899. [9] M.O. Moreira, P.P. Balestrassi, A.P. Paiva, P.F. Ribeiro, B.D.Bonatto, Design of experiments using artificial neural networkensemble for photovoltaic generation forecasting, Renewableand Sustainable Energy Reviews, 135, 2021, 110450. [10] Q. Zhu, Y. Wang, and Y. Luo, Improvement of multi-layersoil moisture prediction using support vector machines andensemble Kalman filter coupled with remote sensing soilmoisture datasets over an agriculture dominant basin in China,Hydrological Processes, 35(4), 2021, e14154. [11] M. Sompop and C. Nawinda, Short-term forecasting ofrenewable energy consumption: Augmentation of a modifiedgrey model with a Kalman filter, Applied Soft ComputingJournal, 87, 2020, 105994. [12] Yang Xiaofeng, Fang Yihang, Zhao Pengzhen, Wang Chenming,Xie Ning, Non-mechanism modeling method for staterecognition of wind turbine, Electric Power, Aug. 2022. [13] N. Korprasertsak and T. Leephakpreeda, Robust short-termprediction of wind power generation under uncertainty viastatistical interpretation of multiple forecasting models, Energy,180, 2019, 387–397. [14] L. Zi and L. Xiaolei, Wind power forecasting of an offshorewind turbine based on high-frequency SCADA data and deeplearning neural network, Energy, 201, 2020, 117693. [15] Z. Gan, C. Li, J. Zhou, and G. Tang, Temporal convolutionalnetworks interval prediction model for wind speed forecasting,electric power systems research, Electric Power SystemsResearch, 191(4), 2021, 106865. [16] Wu Dingan, Zhong JianWei, Wang Xinlei, Xiang Jiaguo, ZengFanwei, Hu kai, Chen Chen, Principal component analysisand long and short-term memory networks for power loadforecasting, Intelligent Processing and Application, 11(08),2021, 4751. [17] Zhang Yunqin, Cheng Qize, Jiang Wenjie, Liu Xiaofeng, ShenLiang, Chen zehua, Photovoltaic power prediction model basedon EMD-PCA-LSTM, Acta Energiae Solaris Sinica, 09, 2021,62–69. [18] S. Sheng, H. Jin, and C. Liu, Short-term and mid-short-termwind power forecasting based on VMD-WSGRU, Power SystemTechnology, 46(03), 2022, 897–904. [19] W.S. Rosenthal, A.M. Tartakovsky, and Z. Huang, EnsembleKalman filter for dynamic state estimation of power gridsstochastically driven by time-correlated mechanical inputpower, IEEE Transactions on Power Systems, 99, 2017,1–10. [20] Fu Yang, Ren Zixu, Wei Shurong, Wang Yang, Huang Lingling,Jia Feng, Ultra-short-term power prediction of offshore windpower based on improved LSTM-TCN model, Proceedings ofthe CSEE, 42(12), 2022,4292–4303. [21] L. Ye, Q. Zhu, and Y. Zhao, Dynamic optimal combinationmodel considering adaptive exponential for ultra-short termwind power prediction, Automation of Electric Power Systems,39(20), 2015, 12–18. [22] Z.M. Zhai, M. Moradi, L.W. Kong, and Y.C. Lai, Model-free tracking control of complex dynamical trajectories withmachine learning, Nature Communications, 14(1), 2023, 5698. [23] K. Dragomiretskiy and Z. Dominique, Variational modedecomposition, IEEE Transactions on Signal Processing, 62(3),2013, 531–544. [24] N.W. Branco, M.S.M. Cavalca, S.F. Stefenon, and V.R.Q.Leithardt, Wavelet LSTM for fault forecasting in electricalpower grids, Sensors, 22(21), 2022, 8323. [25] M. Abou Houran, S.M.S. Bukhari, M.H. Zafar, M. Mansoor, andW. Chen, COA-CNN-LSTM: Coati optimization algorithm-based hybrid deep learning model for PV/wind powerforecasting in smart grid applications, Applied Energy, 349,2023, 121638. [26] Y. Deng, J. Duan, and H. Jia, Ultra-short-term wind powerprediction based on deep learning with independent recurrentneural network via cuckoo algorithm optimized, Power Systemand Clean Energy, 37(09), 2021, 18–26. [27] D. Chang and X. Nan, Short-term photovoltaic powerprediction based on back propagation neural network improvedby hybrid sparrow algorithm, Modern Electric Power, 39(3),2022, 12. [28] K. Dragomiretskiy and D. Zosso, Variational mode decompo-sition, IEEE Transactions on Signal Processing, 62(3), 2014,531–544. [29] C. Li, The research on wind power prediction based on theIPSO-BP neural network model (Wuhan: Wuhan Universityof Science and Technology, 2016). [30] X.S. Yang and X. He, Bat algorithm: Literature reviewand applications, International Journal of Bio-InspiredComputation, 5(3), 2013, 141–149.9
Important Links:
Go Back
