Deep Lyapunov Learning: Embedding the Lyapunov Stability Theory in Interpretable Neural Networks for Transient Stability Assessment

被引：0

作者：

Liu, Jiacheng ^{[1
]}

Liu, Jun ^{[1
]}

Yan, Rudai ^{[2
]}

Ding, Tao ^{[1
]}

机构：

[1] Xi An Jiao Tong Univ, Sch Elect Engn, Xian 710049, Peoples R China

[2] Nanyang Technol Univ, Sch Elect & Elect Engn, Singapore 639798, Singapore

来源：

IEEE TRANSACTIONS ON POWER SYSTEMS | 2024年 / 39卷 / 06期

基金：

国家重点研发计划;

关键词：

Generative adversarial networks; Power system stability; Lyapunov methods; Transient analysis; Training; Asymptotic stability; Stability criteria; Deep Lyapunov learning; gradient adjoint network; Lyapunov function; transient stability assessment;

D O I：

10.1109/TPWRS.2024.3455764

中图分类号：

TM [电工技术]; TN [电子技术、通信技术];

学科分类号：

0808 ; 0809 ;

摘要：

The machine learning-based transient stability assessment (TSA) has shown satisfactory accuracy while been limited by the lack of interpretability. This letter thereby presents a novel deep learning paradigm that naturally embeds the Lyapunov stability theory of dynamic systems, in which approximating Lyapunov functions (LFs) is transformed into traditional regression or classification tasks. The Lyapunov stability theory is firstly extended and then integrated into a specific neural network structure, which consists of a flexible LF approximator and its corresponding gradient adjoint network. It is originally revealed that transient stability binary classification by deep Lyapunov learning (DLL) is equivalent to constructing a semi-analytical LF in the state space. Case studies validate the effectiveness of the proposed DLL scheme.

引用

页码：7437 / 7440

页数：4

共 9 条

[1]

Chen Ricky T. Q., 2018, Advances in Neural Information Processing Systems, V31

[2]

Chiang H. D., 2010, Direct Methods for Stability Analysis of Electric Power Systems: Theoretical Foundation, BCU Methodologies, and Applications, P32

[3] Scientific Machine Learning Through Physics-Informed Neural Networks: Where we are and What's Next [J].

Cuomo, Salvatore ;

Di Cola, Vincenzo Schiano ;

Giampaolo, Fabio ;

Rozza, Gianluigi ;

Raissi, Maziar ;

Piccialli, Francesco .

JOURNAL OF SCIENTIFIC COMPUTING, 2022, 92 (03)

[4] A Neural Lyapunov Approach to Transient Stability Assessment of Power Electronics-Interfaced Networked Microgrids [J].

Huang, Tong ;

Gao, Sicun ;

Xie, Le .

IEEE TRANSACTIONS ON SMART GRID, 2022, 13 (01) :106-118

[5] Discriminative Signal Recognition for Transient Stability Assessment via Discrete Mutual Information Approximation and Eigen Decomposition of Laplacian Matrix [J].

Liu, Jiacheng ;

Liu, Jun ;

Liu, Xiaoming ;

Liu, Xinglei ;

Zhao, Yu .

IEEE TRANSACTIONS ON INDUSTRIAL INFORMATICS, 2024, 20 (04) :5805-5817

[6] High-Precision Identification of Power Quality Disturbances Under Strong Noise Environment Based on FastICA and Random Forest [J].

Liu, Jun ;

Song, Hang ;

Sun, Huiwen ;

Zhao, Hongyan .

IEEE TRANSACTIONS ON INDUSTRIAL INFORMATICS, 2021, 17 (01) :377-387

[7]

Vaswani A, 2017, ADV NEUR IN, V30

[8] Neural Networks Based Lyapunov Functions for Transient Stability Analysis and Assessment of Power Systems [J].

Wang, Tong ;

Wang, Xiaotong ;

Liu, Guangmeng ;

Wang, Zengping ;

Xing, Qipeng .

IEEE TRANSACTIONS ON INDUSTRY APPLICATIONS, 2023, 59 (02) :2626-2638

[9] Neural Lyapunov Control for Power System Transient Stability: A Deep Learning-Based Approach [J].

Zhao, Tianqiao ;

Wang, Jianhui ;

Lu, Xiaonan ;

Du, Yuhua .

IEEE TRANSACTIONS ON POWER SYSTEMS, 2022, 37 (02) :955-966

← 1 →