采用区间动态状态估计的局部不可观系统谐波源定位

doi:10.19595/j.cnki.1000-6753.tces.212084

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摘要传统动态谐波状态估计方法无法有效应对线路参数不确定或局部不可观系统问题,因此用于谐波源定位仍存在较大的局限性。针对上述不足,该文提出基于区间动态状态估计的局部不可观系统谐波源定位方法。首先,利用多端口等效将局部不可观系统转化为等效可观系统,在考虑线路参数不确定性前提下,采用基于误差最优上界的区间卡尔曼滤波算法进行区间动态谐波状态估计;其次,筛选出高度线性相关的状态量,并采用区间中点线性回归辨识回归系数,将其与不可观区域中的节点进行匹配,将匹配度最高的节点视为不可观区域中谐波源所在位置;最后通过算例验证所提方法的可行性与准确性。

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	邵振国
	林洪洲
	陈飞雄
	林俊杰
	张嫣

关键词 ：电能质量, 局部不可观系统, 多端口等效, 区间动态谐波状态估计, 谐波源定位

Abstract：Due to the cost of measurement devices, it is impossible to directly monitor all nodes. Although some nodes can be indirectly monitored by optimizing the configuration of measurement devices, there may still be areas where harmonic information is unobservable in the system. At present, based on the sparse characteristics of harmonic source, the researches estimate harmonic state to locate the harmonic source in the partial unobservable system, but the accuracy of the results is easily affected by factors such as the position of the measurement devices. In addition, the current harmonic state estimation researches are all deterministic state estimation. In fact, due to changes in the field environment, operating status, and equipment aging, the line parameters may be deviated, making it difficult to calculate the accurate harmonic state for deterministic harmonic state estimation. To address the above shortcomings, a harmonic source location method based on interval dynamic state estimation is proposed for the partial unobservable system.
Firstly, the partial unobservable system is transformed into an equivalent observable system by using the multiport equivalence. Secondly, the interval Kalman filter algorithm, which is based on minimal upper bound of error covariance, is used for interval dynamic harmonic state estimation with considering the uncertainty of line parameters. Thirdly, the state variables with linear correlation between boundary nodes are screened out. Then, the linear regression at the midpoint of the interval is used to obtain the regression coefficients, which are applied to be matched with the nodes. The node with the highest matching degree is considered as the position of harmonic source in the unobservable region. Finally, the feasibility and accuracy of the proposed method are demonstrated by simulation and arithmetic case verification.
The simulation results show that, under the partial unobservable system, the traditional harmonic source location method based on compressed sensing incorrectly judges node 7 and node 16 as harmonic sources, but by using the proposed method to transform the system, the calculation results show that the harmonic sources are in the region between node 7 and node 16. Compared with the current solution method, the equivalent method is used to solve the partial unobservable system, which has better accuracy and stability. At the same time, the interval estimated values of equivalent harmonic current cover the actual values and track the dynamic change. Further, according to the harmonic source location strategy, the estimated values are divided into 6 windows, and its R² is calculated for each window, where the results larger than 0.8 threshold are window 3 and window 6, and the corresponding R² are 0.967 8 and 0.914 0 respectively. Through linear regression of the estimated values in the two windows, it can be seen that in the node matching degree curve a, the matching degree of node 9 is larger than that of other nodes, indicating that the main harmonic source is most likely to be located in node 9, so it is judged that the harmonic pollution is located at node 9, which is consistent with the setting. From the node matching degree curve b, it can be seen that in window 6, node 15 has the largest matching degree, indicating that the main harmonic source is the most likely to be located at node 15, so it is judged that harmonic pollution is located at node 15, which is also consistent with the setting.
The following conclusions can be drawn from the simulation analysis: (1) The proposed method using the multiport equivalence, can improve the accuracy of harmonic state estimation results, and identify the unobservable region containing harmonic source. (2) The Optimally bounded interval Kalman filter algorithm is used to estimate the dynamic harmonic state, which can characterize the uncertainty of the harmonic estimation state, and reflect the fluctuation characteristics of the harmonic state. (3) For the existence of harmonic sources in the unobservable region, this proposed method can accurately determine the position of harmonic sources in the unobservable region.

Key words： Power quality partial unobservable system multiport equivalence interval dynamic harmonic state estimation harmonic source location

收稿日期: 2021-12-23

PACS:

TM711

基金资助:国家自然科学基金项目（51777035）和福建自然科学基金重点项目（2020J02028）资助

通讯作者: 邵振国男,1970年生,教授,博士生导师,研究方向为高渗透率新能源电网建模与仿真、电能质量分析与治理等。E-mail：shao.zg@fzu.edu.cn

作者简介: 林洪洲男,1997年生,硕士研究生,研究方向为电能质量分析与治理等。E-mail：523558952@qq.com

引用本文:

邵振国, 林洪洲, 陈飞雄, 林俊杰, 张嫣. 采用区间动态状态估计的局部不可观系统谐波源定位[J]. 电工技术学报, 2023, 38(9): 2391-2402. Shao Zhenguo, Lin Hongzhou, Chen Feixiong, Lin Junjie, Zhang Yan. Harmonic Source Location in the Partial Unobservable System Based on Interval Dynamic State Estimation. Transactions of China Electrotechnical Society, 2023, 38(9): 2391-2402.

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