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Main Authors: Fan, Guodong, Zhou, Boru, Meng, Chengwen, Pang, Tengwei, Zhang, Xi, Du, Mingshu, Zhao, Wei
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.12152
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author Fan, Guodong
Zhou, Boru
Meng, Chengwen
Pang, Tengwei
Zhang, Xi
Du, Mingshu
Zhao, Wei
author_facet Fan, Guodong
Zhou, Boru
Meng, Chengwen
Pang, Tengwei
Zhang, Xi
Du, Mingshu
Zhao, Wei
contents This paper develops a comprehensive physics-based model (PBM) that spans a wide operational range, including varying temperatures, charge/discharge conditions, and real-world field data cycles. The PBM incorporates key factors such as hysteresis effects, concentration-dependent diffusivity, and the Arrhenius law to provide a realistic depiction of battery behavior. Additionally, the paper presents an in-depth analysis comparing the PBM with an equivalent-circuit model (ECM) for accurately capturing the dynamics of lithium-ion batteries under diverse operating conditions. To ensure a fair comparison, both the PBM and ECM are rigorously calibrated and validated through parameter identification and testing across 55 different operating conditions. To the best of the authors' knowledge, this represents the most comprehensive model calibration and validation effort for PBM and ECM in the literature to date, encompassing large temperature variations (-20 to 40°C), various charging/discharging C-rates, and real-world driving cycles. Comparative analysis between the PBM and ECM highlights key differences in accuracy, computational complexity, parameterization requirements, and performance under varying temperature conditions. appropriate models for battery management applications.
format Preprint
id arxiv_https___arxiv_org_abs_2411_12152
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Development of a Comprehensive Physics-Based Battery Model and Its Multidimensional Comparison with an Equivalent-Circuit Model: Accuracy, Complexity, and Real-World Performance under Varying Conditions
Fan, Guodong
Zhou, Boru
Meng, Chengwen
Pang, Tengwei
Zhang, Xi
Du, Mingshu
Zhao, Wei
Systems and Control
This paper develops a comprehensive physics-based model (PBM) that spans a wide operational range, including varying temperatures, charge/discharge conditions, and real-world field data cycles. The PBM incorporates key factors such as hysteresis effects, concentration-dependent diffusivity, and the Arrhenius law to provide a realistic depiction of battery behavior. Additionally, the paper presents an in-depth analysis comparing the PBM with an equivalent-circuit model (ECM) for accurately capturing the dynamics of lithium-ion batteries under diverse operating conditions. To ensure a fair comparison, both the PBM and ECM are rigorously calibrated and validated through parameter identification and testing across 55 different operating conditions. To the best of the authors' knowledge, this represents the most comprehensive model calibration and validation effort for PBM and ECM in the literature to date, encompassing large temperature variations (-20 to 40°C), various charging/discharging C-rates, and real-world driving cycles. Comparative analysis between the PBM and ECM highlights key differences in accuracy, computational complexity, parameterization requirements, and performance under varying temperature conditions. appropriate models for battery management applications.
title Development of a Comprehensive Physics-Based Battery Model and Its Multidimensional Comparison with an Equivalent-Circuit Model: Accuracy, Complexity, and Real-World Performance under Varying Conditions
topic Systems and Control
url https://arxiv.org/abs/2411.12152