Review of State Estimation of Lithium-ion Battery with Machine Learning

被引：0

作者：

Xie Y. ^{[1
]}

Cheng X. ^{[1
]}

机构：

[1] School of Mechanical Engineering, National Engineering Lab for Electric Vehicles, Beijing Institute of Technology, Beijing

来源：

Cheng, Ximing (cxm2004@bit.edu.com) | 1720年 / SAE-China卷 / 43期

关键词：

Lithium-ion battery; Machine learning; RUL; SOC; SOH;

D O I：

10.19562/j.chinasae.qcgc.2021.11.018

中图分类号：

学科分类号：

摘要：

This paper aims to give a comprehensive review on the research progress in the field of the estimation of the states of lithium-ion battery, including the state of charge (SOC), state of health (SOH) and residual useful life (RUL). Firstly, the application status of machine learning method to the estimation of battery states are expounded. Then, five specific implemental links of machine learning methods for battery state estimation are summarized, including data preparation, model selection and evaluation, hyperparameter determination, data preprocessing and model training, and an evaluation method of learning algorithms is proposed in terms of fusion accuracy, implementation cost and robustness. Finally, the problem of scene adaptability in determining hyperparameters is pointed out, with a suggestion put forward: establishing multi-regional, cross-seasonal, multi-mode and long-term driving cycle database of traction battery, so as to promote the research on the practicability and universality of machine learning algorithms for battery state estimation. © 2021, Society of Automotive Engineers of China. All right reserved.

引用

页码：1720 / 1729

页数：9

共 105 条

[11] ASHWIN T R, CHUNG Y M, WANG J., Capacity fade modelling of lithium-ion battery under cyclic loading conditions, Journal of Power Sources, 328, pp. 586-598, (2016)
[12] WANG A, CHEN H, JIN P, Et al., RUL estimation of lithium-ion power battery based on DEKF algorithm, Institute of Electrical and Electronics Engineers Inc, pp. 1851-1856, (2019)
[13] HECHT-NIELSEN R., Theory of the backpropagation neural network, pp. 593-605, (1989)
[14] PARK J, SANDBERG I W., Universal approximation using radial⁃basis⁃function networks, Neural Computation, 3, 2, pp. 246-257, (1991)
[15] LIU X, LI K, WU J, Et al., State of charge estimation for traction battery based on EKF⁃SVM algorithm, Automotive Engineering, 42, 11, pp. 1522-1528, (2020)
[16] DAI H, JIANG B, WEI X, Et al., Capacity estimation of lithium-ion batteries based on charging curve features, Journal of Mechanical Engineering, 55, 20, pp. 52-59, (2019)
[17] ZHOU D, SONG X, LU W, Et al., Real⁃time SOH estimation algorithm for lithium⁃ion batteries based on daily segment charging data, Proceedings of the Chinese Society of Electrical Engineering, 39, 1, pp. 105-111, (2019)
[18] HU X, YANG X, FENG F, Et al., A particle filter and long short⁃term memory fusion technique for lithium⁃ion battery remaining useful life prediction, Journal of Dynamic Systems, Measurement and Control, Transactions of the ASME, 143, 6, (2021)
[19] BAO W, GE J., Study on battery SOC prediction method for electric bus based on sparsely sampled data, Automotive Engineering, 42, 3, pp. 367-374, (2020)
[20] HANNAN M A, LIPU M, HUSSAIN A, Et al., Neural network approach for estimating state of charge of lithium⁃ion battery using backtracking search algorithm, IEEE Access, 6, pp. 10069-10079, (2018)

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