Transient Stability Assessment of Power System Based on Multi-granularity Neighborhood Rough Set and Improved Bi-directional Long-short-term Memory Network

doi:10.11985/2023.03.025

Abstract

Abstract:

At present, data-driven deep learning algorithm is widely used in the field of power system transient analysis, but in practice, there are few transient instability in the measured data samples of power system, and insufficient attention is paid to the instability samples, resulting in the weak anti-interference and generalization ability of the classification model, which affects the evaluation performance of the whole model. To solve this problem, a power system transient stability assessment method based on multi-granularity neighborhood rough set and improved bi-directional long-short-term memory network(IM-Bi-LSTM) is proposed. Firstly, the neighborhood rough set is used to find the optimal reduction subset at different granularity levels, and then the BiLSTM neural network is used to extract the timing information of the feature subset, and the attention model is introduced into the model to add more weights to the features related to the unstable samples. Through the focus loss function, the weight coefficient is introduced to adjust the tendency of model training, solve the imbalance between unstable samples and transient stability samples, and improve the evaluation performance of the model. The experimental results on the IEEE 10 machine 39 bus system show that compared with other algorithms, the proposed method has better classification accuracy and more stable results.

Key words: Power system, neighborhood rough sets, bi-directional long-short-term memory network, attention model, focus loss, transient stability assessment

CLC Number:

TM712

LI Zhibing, XIAO Jianmei, WANG Xihuai. Transient Stability Assessment of Power System Based on Multi-granularity Neighborhood Rough Set and Improved Bi-directional Long-short-term Memory Network[J]. Journal of Electrical Engineering, 2023, 18(3): 232-241.

Figures/Tables 12

References 22

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特征	特征集描述
1	发电机机械功率平均值
2	发电机加速功率的平均值
3	发电机加速度方差
4	发电机所受冲击最大值
5	发电机所受冲击最小值
6	转子加速度平均值
7	转子相对加速度最大值
8	转子角度最大值与最小值之差
9	转子角速度最大值与最小值之差
10	转子动能最大值与最小值之差
11	转子动能最大值
12	转子动能平均值
13	发电机所受冲击最大值
14	发电机所受冲击最小值
15	转子角度最大值与最小值之差
16	转子角速度最大值与最小值之差
17	转子动能最大值与最小值之差
18	转子动能最大值
19	转子动能平均值
20	有功功率总和
21	功角极值
22	发电机加速功率方差
23	系统的总能量变化

评估指标	真实标签
评估指标	稳定	失稳
稳定	TP	FP
失稳	FN	TN

指标	表达式
ACC	$\frac{T P+T N}{T P+T N+F N+F P}$
MA	$\frac{F N}{T P+F N} $
FA	$\frac{F P}{F P+T N} $
G-mean	$\sqrt{(1-M A)(1-F A)}$

粒度级别	约简特征子集
R1	23,15,21,6,22,4,20,13,5,3,14,19,2
R2	23,15,21,22,10,4,20,13,5,3
R3	23,15,17,5,21,22,20,3,6,13,4,14,2,7,19
R4	18,23,15,5,21,10,22,3,14,20,4,13,2

粒度级别	ACC(%)	MA(%)	FA(%)	G-mean(%)
R1	98.30	1.31	3.14	97.77
R2	96.28	2.36	5.35	96.13
R3	95.14	4.20	5.66	95.07
R4	93.99	1.05	11.95	93.34
原始数据集	95.57	5.51	3.15	95.66