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Enhanced multi-state estimation methods for lithium-ion batteries considering temperature uncertainties.

Takyi-Aninakwa, Paul; Wang, Shunli; Zhang, Hongying; Xiao, Yang; Fernandez, Carlos

Authors

Paul Takyi-Aninakwa

Shunli Wang

Hongying Zhang

Yang Xiao



Abstract

Due to their high energy density and minimal emissions, lithium-ion batteries are frequently employed in electric vehicles (EVs). Accurate estimation of the micro-parameters, state of charge (SOC), and state of health (SOH) are a few primary monitoring functions of the battery management system (BMS) to increase the battery's efficiency and safety under various operating conditions. This paper proposes a SOC and SOH co-estimation method by adopting an ensemble empirical mode decomposition method with adaptive noise and an autoencoder (EEMDA) to extract, decompose, and reconstruct the full-scale charging voltage and current data for a dual extended Kalman filter (DEKF) with multi-parameter and time-scale updates for accurate estimation based on a variable forgetting factor limited memory recursive least squares (VFF-LMRLS) method. The VFF-LMRLS method is used to solve the data saturation phenomenon and identify the battery's characteristic micro-parameters based on a proposed dynamic migration second-order resistor-capacitor equivalent circuit model under different operating states. Battery tests are conducted at temperatures ranging from −10 to 50 °C under complex working conditions. Using the VFF-LMRLS method, the effects of different temperatures on the micro-parameters are discussed. The SOC and SOH results of the proposed EEMDA-DEKF method based on the dynamic migration battery model show that the mean absolute error and root mean square error metrics have the least values of 0.0233% and 0.0252%, which signify an optimal performance improvement of 93.26% and 93.66%, respectively, compared to the conventional DEKF method. Based on the experimental results and analyses, the proposed method has a high degree of accuracy and robustness, which makes it feasible for battery monitoring and prognostic BMS applications.

Citation

TAKYI-ANINAKWA, P., WANG, S., ZHANG, H., XIAO, Y. and FERNANDEZ, C. 2023. Enhanced multi-state estimation methods for lithium-ion batteries considering temperature uncertainties. Journal of energy storage [online], 66, article number 107495. Available from: https://doi.org/10.1016/j.est.2023.107495

Journal Article Type Article
Acceptance Date Apr 20, 2023
Online Publication Date May 1, 2023
Publication Date Aug 30, 2023
Deposit Date May 15, 2023
Publicly Available Date May 2, 2024
Journal Journal of energy storage
Print ISSN 2352-152X
Electronic ISSN 2352-1538
Publisher Elsevier
Peer Reviewed Peer Reviewed
Volume 66
Article Number 107495
DOI https://doi.org/10.1016/j.est.2023.107495
Keywords State of charge; State of health; Dynamic migration second-order resistor-capacitor equivalent circuit model; Variable forgetting factor limited memory recursive least squares method; Ensemble empirical mode decomposition autoencoding method
Public URL https://rgu-repository.worktribe.com/output/1952939