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Main Authors: Cheng, Yuanhao, Bai, Hanyu, Liang, Yichen, Cui, Xiaofan, Jiang, Weiren, Song, Ziyou
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.10044
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author Cheng, Yuanhao
Bai, Hanyu
Liang, Yichen
Cui, Xiaofan
Jiang, Weiren
Song, Ziyou
author_facet Cheng, Yuanhao
Bai, Hanyu
Liang, Yichen
Cui, Xiaofan
Jiang, Weiren
Song, Ziyou
contents Battery degradation modes influence the aging behavior of Li-ion batteries, leading to accelerated capacity loss and potential safety issues. Quantifying these aging mechanisms poses challenges for both online and offline diagnostics in charging station applications. Data-driven algorithms have emerged as effective tools for addressing state-of-health issues by learning hard-to-model electrochemical properties from data. This paper presents a data-driven method for quantifying battery degradation modes. Ninety-one statistical features are extracted from the incremental capacity curve derived from 1/3C charging data. These features are then screened based on dispersion, contribution, and correlation. Subsequently, machine learning models, including four baseline algorithms and a feedforward neural network, are used to estimate the degradation modes. Experimental validation indicates that the feedforward neural network outperforms the others, achieving a root mean square error of around 10\% across all three degradation modes (i.e., loss of lithium inventory, loss of active material on the positive electrode, and loss of active material on the negative electrode). The findings in this paper demonstrate the potential of machine learning for diagnosing battery degradation modes in charging station scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2412_10044
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Data-Driven Quantification of Battery Degradation Modes via Critical Features from Charging
Cheng, Yuanhao
Bai, Hanyu
Liang, Yichen
Cui, Xiaofan
Jiang, Weiren
Song, Ziyou
Signal Processing
Battery degradation modes influence the aging behavior of Li-ion batteries, leading to accelerated capacity loss and potential safety issues. Quantifying these aging mechanisms poses challenges for both online and offline diagnostics in charging station applications. Data-driven algorithms have emerged as effective tools for addressing state-of-health issues by learning hard-to-model electrochemical properties from data. This paper presents a data-driven method for quantifying battery degradation modes. Ninety-one statistical features are extracted from the incremental capacity curve derived from 1/3C charging data. These features are then screened based on dispersion, contribution, and correlation. Subsequently, machine learning models, including four baseline algorithms and a feedforward neural network, are used to estimate the degradation modes. Experimental validation indicates that the feedforward neural network outperforms the others, achieving a root mean square error of around 10\% across all three degradation modes (i.e., loss of lithium inventory, loss of active material on the positive electrode, and loss of active material on the negative electrode). The findings in this paper demonstrate the potential of machine learning for diagnosing battery degradation modes in charging station scenarios.
title Data-Driven Quantification of Battery Degradation Modes via Critical Features from Charging
topic Signal Processing
url https://arxiv.org/abs/2412.10044