基于多维度多尺度特征的锂离子电池RUL估计方法

doi:10.19562/j.chinasae.qcgc.2024.10.016

Abstract

Abstract:

Accurately predicting the remaining useful life （RUL） of lithium-ion batteries is important for the efficient and safe operation of energy storage systems. For the deficiencies of existing data-driven methods for RUL estimation， which extract aging features non-comprehensively enough and need to predict health state changes before estimating RUL， a RUL estimation method using multi-dimensional and multi-scale features is proposed in this paper to directly estimate the RUL of a battery using constant-current charging voltage segment data. The model maps RUL by extracting aging features of voltage segments using different scale convolution operation after dimensionally transforming the data. The model is validated using publicly available datasets from the University of Oxford， NASA， and the University of Maryland. The validation results show that the model can directly estimate the RUL of the batteries using the voltage segment data without the need of the current historical SOH of the batteries as the training data， which has higher accuracy and universality compared to fixed scale features based on a single dimension.

Key words: lithium-ion battery, remaining useful life, multi-dimensional and multi-scale features, deep learning

Qiuyan Zhang,Ze Cheng,Xu Liu. RUL Estimation Method for Lithium-ion Batteries Based on Multi-dimensional and Multi-scale Features[J].Automotive Engineering, 2024, 46(10): 1897-1903.

Figures/Tables 17

References 16

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电池	多维多尺度	二维固定	一维固定
Cell1	1.29	2.31	2.44
Cell8	1.15	2.29	2.48

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RUL Estimation Method for Lithium-ion Batteries Based on Multi-dimensional and Multi-scale Features

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