Forced Oscillation Source Location in Power System Using Wavelet Dissipation Energy Spectrum
Jiang Tao1, Gao Han1, Li Xiaojing2, Chen Houhe1, Li Guoqing1
1. Key Laboratory of Modern Power System Simulation and Control & Renewable Energy Technology Ministry of Education Northeast Electric Power University Jilin 132012 China; 2. State Grid Jilin Electric Power Company Changchun 130021 China
摘要 快速、准确地定位强迫振荡源是抑制电力系统强迫功率振荡的关键。目前,基于广域量测信息的电力系统强迫振荡源定位方法大多基于时域耗散能量流理论,其计算过程较为复杂,计算效率有待提高。首先,提出一种基于小波耗散能量谱(WDES)的电力系统强迫振荡源频域定位方法,该方法首先将电力系统广域测量信息进行连续小波变换,得到各广域量测信息的小波系数矩阵;然后,根据获得小波系数矩阵定义小波耗散能量谱,阐述小波耗散能量谱和传统时域耗散能量流的关联关系;进而,由小波耗散能量谱的跃变特性确定系统的强迫振荡频率;再根据各发电机在强迫振荡频率处的小波耗散能量谱准确定位振荡源;最后,将所提方法应用到WECC-179节点测试系统和ISO New England中进行仿真和验证,结果验证了所提方法的准确性和有效性。
Abstract:Fast and accurate location of the forced oscillation source is the key to eliminate the forced oscillation source. At present, most of the methods for locating forced oscillation sources in power systems adopt the theory of dissipating energy flow (DEF) in time domain via wide-area measurement information. However, when the traditional time-domain DEF is used to determine the oscillation source, the required wide-area measurement information needs to be converted into "time-domain, frequent-domain, time-domain" to extract the time-domain component of forced oscillation in the wide-area measurement information, so as to improve the accuracy of the oscillation source location. The calculation process is relatively complex and the computational efficiency is low. solve this problem, this paper proposes a method of locating the forced oscillation source in the frequency domain based on the wavelet dissipation energy spectrum (WDES), and realizes the forced oscillation source localization in the frequency domain to improve the computational efficiency of the oscillation source localization. Firstly, the wavelet coefficient matrix of each wide area measurement information is obtained by using continuous wavelet transform (CWT). On this basis, the CWT multiplication formula is combined with the traditional time-domain DEF formula to construct the WDES, and the relationship between the WDES and time-domain DEF is proved. Then, the trend of the WDES was analyzed, and the forced oscillation frequency of the system was determined according to its jump characteristics. Further, the WDES of each generator at the forced oscillation frequency is extracted to locate the forced oscillation source accurately. Finally, the proposed method is evaluated by WECC 179-bus test system and ISO New England system. The simulation results show that the proposed method can accurately and effectively locate the single oscillation source, double oscillation source and real oscillation source in WECC 179-bus test system and ISO New England system, respectively. At the same time, compared with the traditional time-domain DEF method and time-frequency DEF method, the computational efficiency of the proposed method is improved by 32.78% and 31.39%, respectively, in the single oscillation source location of WECC 179-bus test system in scenario 1. In the single oscillation source location of WECC 179-bus test system in scenario 2, the computational efficiency of the proposed method is improved by 32.17% and 31.47% compared with the traditional time-domain DEF method and time-frequency DEF method, respectively. In the ISO New England system, compared with the traditional time-domain DEF method and time-frequency DEF method, the computational efficiency of the proposed oscillation source location method is improved by 30.10% and 24.16%, respectively. Obviously, the proposed method has higher computational efficiency of the forced oscillation source. The following conclusions can be drawn from the simulation analysis: (1) the proposed method based on WDES can accurately and effectively locate the forced oscillation source from the wide-area measurement information of the power system. (2) Compared with the localization method of DEF in time-domain and time-frequency domain, the proposed localization method of forced oscillation source in frequency domain based on WDES effectively improves the computational efficiency of forced oscillation source. (3) The proposed WDES is equivalent to the time-domain DEF and the time-frequency DEF. It can be considered as a form of time-domain DEF and time-frequency DEF in frequency domain. From the perspective of frequency domain energy spectrum, it provides a new solution for locating power system forced oscillation source through the field measurements.
姜涛, 高浛, 李筱静, 陈厚合, 李国庆. 基于小波耗散能量谱的电力系统强迫振荡源定位[J]. 电工技术学报, 2023, 38(7): 1737-1750.
Jiang Tao, Gao Han, Li Xiaojing, Chen Houhe, Li Guoqing. Forced Oscillation Source Location in Power System Using Wavelet Dissipation Energy Spectrum. Transactions of China Electrotechnical Society, 2023, 38(7): 1737-1750.
[1] 冯双, 陈佳宁, 汤奕, 等. 基于SPWVD图像和深度迁移学习的强迫振荡源定位方法[J]. 电力系统自动化, 2020, 44(17): 78-87. Feng Shuang, Chen Jianing, Tang Yi, et al.Location method of forced oscillation source based on SPWVD image and deep transfer learning[J]. Automation of Electric Power Systems, 2020, 44(17): 78-87. [2] 薛安成, 王嘉伟. 基于非光滑分岔的单机水电系统超低频频率振荡机理分析[J]. 电工技术学报, 2020, 35(7): 1489-1497. Xue Ancheng, Wang Jiawei.Mechanism analysis of ultra-low frequency oscillation of single hydropower system based on non-smooth bifurcation[J]. Transactions of China Electrotechnical Society, 2020, 35(7): 1489-1497. [3] 胡鹏, 艾欣, 肖仕武, 等. 静止无功发生器序阻抗建模及对次同步振荡影响因素的分析[J]. 电工技术学报, 2020, 35(17): 3703-3713. Hu Peng, Ai Xin, Xiao Shiwu, et al.Sequence impedance of static var generator and analysis of influencing factors on subsynchronous oscillation[J]. Transactions of China Electrotechnical Society, 2020, 35(17): 3703-3713. [4] Chevalier S, Vorobev P, Turitsyn K.A Bayesian approach to forced oscillation source location given uncertain generator parameters[J]. IEEE Transactions on Power Systems, 2019, 34(2): 1641-1649. [5] 何映光, 刘焘. 汽轮机阀切换操作不当引发的电网低频振荡分析[J]. 电力自动化设备, 2010, 30(5): 142-145. He Yingguang, Liu Tao.Analysis of power grid low frequency oscillation caused by improper turbine valve switchover[J]. Electric Power Automation Equipment, 2010, 30(5): 142-145. [6] Zhu Lin, Yu Wenpeng, Jiang Zhihao, et al.A comprehensive method to mitigate forced oscillations in large interconnected power grids[J]. IEEE Access, 2021, 9: 22503-22515. [7] 栾某德. 电力系统强迫振荡扰动源定位研究[D]. 杭州: 浙江大学, 2020. [8] 王茂海, 孙昊. 强迫功率振荡源的在线定位分析技术[J]. 中国电机工程学报, 2014, 34(34): 6209-6215. Wang Maohai, Sun Hao.An analysis method for forced power oscillation source detection[J]. Proceedings of the CSEE, 2014, 34(34): 6209-6215. [9] 余一平, 闵勇, 陈磊. 多机电力系统强迫功率振荡稳态响应特性分析[J]. 电力系统自动化, 2009, 33(22): 5-9. Yu Yiping, Min Yong, Chen Lei.Analysis of forced power oscillation steady-state response properties in multi-machine power systems[J]. Automation of Electric Power Systems, 2009, 33(22): 5-9. [10] 余一平, 闵勇, 陈磊, 等. 周期性负荷扰动引发强迫功率振荡分析[J]. 电力系统自动化, 2010, 34(6): 7-11, 47. Yu Yiping, Min Yong, Chen Lei, et al.Analysis of forced power oscillation caused by continuous cyclical load disturbances[J]. Automation of Electric Power Systems, 2010, 34(6): 7-11, 47. [11] 董超, 云雷, 刘涤尘, 等. 原动机周期性扰动引发强迫功率振荡特性研究[J]. 电网与清洁能源, 2012, 28(4): 35-41, 46. Dong Chao, Yun Lei, Liu Dichen, et al.Research on the properties of forced oscillations caused by turbine's periodic disturbance[J]. Power System and Clean Energy, 2012, 28(4): 35-41, 46. [12] 余一平, 闵勇, 陈磊, 等. 基于能量函数的强迫功率振荡扰动源定位[J]. 电力系统自动化, 2010, 34(5): 1-6. Yu Yiping, Min Yong, Chen Lei, et al.Disturbance source location of forced power oscillation using energy functions[J]. Automation of Electric Power Systems, 2010, 34(5): 1-6. [13] 李文锋, 郭剑波, 李莹, 等. 基于WAMS的电力系统功率振荡分析与振荡源定位(1)割集能量法[J]. 中国电机工程学报, 2013, 33(25): 41-46, 9. Li Wenfeng, Guo Jianbo, Li Ying, et al.Power system oscillation analysis and oscillation source location based on WAMS part 1: method of cutset energy[J]. Proceedings of the CSEE, 2013, 33(25): 41-46, 9. [14] Chen Lei, Min Yong, Hu Wei.An energy-based method for location of power system oscillation source[J]. IEEE Transactions on Power Systems, 2013, 28(2): 828-836. [15] Maslennikov S, Wang Bin, Litvinov E.Dissipating energy flow method for locating the source of sustained oscillations[J]. International Journal of Electrical Power & Energy Systems, 2017, 88: 55-62. [16] Chen Lei, Sun Ming, Yong Min, et al.Online monitoring of generator damping using dissipation energy flow computed from ambient data[J]. IET Generation, Transmission and Distribution, 2017, 11(18): 4430-4435. [17] Estevez P G, Marchi P, Galarza C, et al.Non-stationary power system forced oscillation analysis using synchrosqueezing transform[J]. IEEE Transactions on Power Systems, 2021, 36(2): 1583-1593. [18] 姜涛, 李孟豪, 李雪, 等. 电力系统强迫振荡源的时频域定位方法[J]. 电力系统自动化, 2021, 45(9): 98-106. Jiang Tao, Li Menghao, Li Xue, et al.Time-frequency domain location method for forced oscillation source in power system[J]. Automation of Electric Power Systems, 2021, 45(9): 98-106. [19] 李雪, 于洋, 姜涛, 等. 基于稀疏增强动态解耦的电力系统振荡模式与模态辨识方法[J]. 电工技术学报, 2021, 36(13): 2832-2843. Li Xue, Yu Yang, Jiang Tao, et al.Sparsity promoting dynamic mode decomposition based dominant modes and mode shapes estimation in bulk power grid[J]. Transactions of China Electrotechnical Society, 2021, 36(13): 2832-2843. [20] 李雪, 于洋, 姜涛, 等. 基于最优变量投影的电力系统主导振荡参数综合辨识[J]. 电工技术学报, 2022, 37(1): 165-178. Li Xue, Yu Yang, Jiang Tao, et al.Estimating dominant oscillation characteristics from measurement responses in power systems utilizing optimized variable projection[J]. Transactions of China Electrotechnical Society, 2022, 37(1): 165-178. [21] 刘素贞, 魏建, 张闯, 等. 基于FPGA的超声信号自适应滤波与特征提取[J]. 电工技术学报, 2020, 35(13): 2870-2878. Liu Suzhen, Wei Jian, Zhang Chuang, et al.Adaptive filtering and feature extraction of ultrasonic signal based on FPGA[J]. Transactions of China Electrotechnical Society, 2020, 35(13): 2870-2878. [22] 李国庆, 王丹, 姜涛, 等. 基于递归连续小波变换的电力系统振荡模式辨识[J]. 电力自动化设备, 2016, 36(9): 8-16. Li Guoqing, Wang Dan, Jiang Tao, et al.Power system oscillation mode identification based on recursive continuous wavelet transform[J]. Electric Power Automation Equipment, 2016, 36(9): 8-16. [23] Al Abdi R M, Jarrah M. Cardiac disease classification using total variation denoising and morlet continuous wavelet transformation of ECG signals[C]//2018 IEEE 14th International Colloquium on Signal Processing & Its Applications (CSPA), Penang, Malaysia, 2018: 57-60. [24] Liu W Y, Gao Q W, Zhang Y.A novel wind turbine de-noising method based on the Genetic Algorithm optimal Mexican hat wavelet[C]//2016 13th International Conference on Ubiquitous Robots and Ambient Intelligence (URAI), Xi'an, China, 2016: 1003-1006. [25] Shen Yongpeng, Sun Jianbin, Yang Xiaoliang, et al.Symlets wavelet transform based power management of hybrid energy storage system[C]//2020 IEEE 4th Conference on Energy Internet and Energy System Integration (EI2), Wuhan, China, 2021: 2556-2561. [26] Jiang Tao, Yuan Haoyu, Li Guoqing, et al.A spatial-temporal decomposition approach for systematically tracking dominant modes, mode shapes and coherent groups in power systems[J]. IET Generation, Transmission and Distribution, 2017, 11(8): 1889-1900. [27] Xie Ruichao, Trudnowski D.Tracking the damping contribution of a power system component under ambient conditions[J]. IEEE Transactions on Power Systems, 2018, 33(1): 1116-1117. [28] Wang Bin, Sun Kai.Formulation and characterization of power system electromechanical oscillations[J]. IEEE Transactions on Power Systems, 2016, 31(6): 5082-5093. [29] 姜涛, 刘方正, 陈厚合, 等. 基于多通道快速傅里叶小波变换的电力系统主导振荡模式及模态协同辨识方法研究[J]. 电力自动化设备, 2019, 39(7): 125-132. Jiang Tao, Liu Fangzheng, Chen Houhe, et al.Cooperated identification method of dominant oscillation modes and mode shapes for power system based on multi-channel fast Fourier transform based continuous wavelet transform[J]. Electric Power Automation Equipment, 2019, 39(7): 125-132. [30] http://web.eecs.utk.edu/~kaisun/Oscillation/actualcases.html.
2023, Vol. 38 
