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Main Authors: Zhao, Yanbin, Liu, Hao, Deng, Zhihua, Li, Tong, Jiang, Haoyi, Ling, Zhenfei, Wang, Xingkai, Zhang, Lei, Ouyang, Xiaoping
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.05364
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author Zhao, Yanbin
Liu, Hao
Deng, Zhihua
Li, Tong
Jiang, Haoyi
Ling, Zhenfei
Wang, Xingkai
Zhang, Lei
Ouyang, Xiaoping
author_facet Zhao, Yanbin
Liu, Hao
Deng, Zhihua
Li, Tong
Jiang, Haoyi
Ling, Zhenfei
Wang, Xingkai
Zhang, Lei
Ouyang, Xiaoping
contents Aiming at the dilemma that most laboratory data-driven diagnostic and prognostic methods cannot be applied to field batteries in passenger cars and energy storage systems, this paper proposes a method to bridge field data and laboratory data using machine learning. Only two field real impedances corresponding to a medium frequency and a high frequency are needed to predict laboratory real impedance curve, laboratory charge/discharge curve, and laboratory relaxation curve. Based on the predicted laboratory data, laboratory data-driven methods can be used for field battery diagnosis and prognosis. Compared with the field data-driven methods based on massive historical field data, the proposed method has the advantages of higher accuracy, lower cost, faster speed, readily available, and no use of private data. The proposed method is tested using two open-source datasets containing 249 NMC cells. For a test set containing 76 cells, the mean absolute percentage errors of laboratory real impedance curve, charge curve, and discharge curve prediction results are 0.85%, 4.72%, and 2.69%, respectively. This work fills the gap between laboratory data-driven diagnostic and prognostic methods and field battery applications, making all laboratory data-driven methods applicable to field battery diagnosis and prognosis. Furthermore, this work overturns the fixed path of developing field battery diagnostic and prognostic methods based on massive field historical data, opening up new research and breakthrough directions for field battery diagnosis and prognosis.
format Preprint
id arxiv_https___arxiv_org_abs_2505_05364
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Machine learning bridging battery field data and laboratory data
Zhao, Yanbin
Liu, Hao
Deng, Zhihua
Li, Tong
Jiang, Haoyi
Ling, Zhenfei
Wang, Xingkai
Zhang, Lei
Ouyang, Xiaoping
Applications
Aiming at the dilemma that most laboratory data-driven diagnostic and prognostic methods cannot be applied to field batteries in passenger cars and energy storage systems, this paper proposes a method to bridge field data and laboratory data using machine learning. Only two field real impedances corresponding to a medium frequency and a high frequency are needed to predict laboratory real impedance curve, laboratory charge/discharge curve, and laboratory relaxation curve. Based on the predicted laboratory data, laboratory data-driven methods can be used for field battery diagnosis and prognosis. Compared with the field data-driven methods based on massive historical field data, the proposed method has the advantages of higher accuracy, lower cost, faster speed, readily available, and no use of private data. The proposed method is tested using two open-source datasets containing 249 NMC cells. For a test set containing 76 cells, the mean absolute percentage errors of laboratory real impedance curve, charge curve, and discharge curve prediction results are 0.85%, 4.72%, and 2.69%, respectively. This work fills the gap between laboratory data-driven diagnostic and prognostic methods and field battery applications, making all laboratory data-driven methods applicable to field battery diagnosis and prognosis. Furthermore, this work overturns the fixed path of developing field battery diagnostic and prognostic methods based on massive field historical data, opening up new research and breakthrough directions for field battery diagnosis and prognosis.
title Machine learning bridging battery field data and laboratory data
topic Applications
url https://arxiv.org/abs/2505.05364