Deep learning driven battery voltage-capacity curve prediction utilizing short-term relaxation voltage

IF 15 1区 工程技术 Q1 ENERGY & FUELS Etransportation Pub Date : 2024-10-30 DOI:10.1016/j.etran.2024.100378
Aihua Tang , Yuchen Xu , Pan Liu , Jinpeng Tian , Zikang Wu , Yuanzhi Hu , Quanqing Yu
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Abstract

Accurate monitoring of the capacity degradation of batteries is critical to their stable operation. However, evaluating the maximum capacity with limited cycle information alone is insufficient to fully indicate the extent of battery degradation. Here, this study propose a battery degradation monitoring method using relaxation voltage combined with encoder-decoder to extend traditional maximum capacity estimation to the entire voltage-capacity (V-Q) curve estimation. The encoder-decoder is constructed using a two-stage training strategy of unsupervised pre-training and transfer learning. Firstly, the short-time relaxation voltage sequence are input the autoencoder for unsupervised pre-training. Through this auto-encoding process, the encoder acquires feature learning capability on the unlabeled relaxation voltages under the same test conditions. Subsequently, the two-stage training process is completed by freezing the encoder weights and performing transfer learning on the decoder to map the relaxation voltage sequence to its corresponding V-Q curve. The proposed method achieves more advanced prediction performance than direct training at the same epochs. This means higher accuracy in using V-Q curves and the derived incremental capacity curves for comprehensive battery degradation monitoring. Validated on 130 battery samples from different laboratories, the proposed method predicts high-fidelity V-Q curves with a root-mean-square error of less than 0.03 Ah. This study highlights the ability to adopt relaxation voltages for battery degradation monitoring, which is expected to enable fast and comprehensive aging diagnostics in non-constant current charging situations due to the short relaxation time required and without additional cycling information.

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利用短期弛豫电压进行深度学习驱动的电池电压-容量曲线预测
准确监控电池容量衰减对电池的稳定运行至关重要。然而,仅凭有限的循环信息来评估最大容量并不足以充分显示电池退化的程度。在此,本研究提出了一种使用松弛电压结合编码器-解码器的电池劣化监测方法,将传统的最大容量估算扩展到整个电压-容量(V-Q)曲线估算。编码器-解码器采用无监督预训练和迁移学习的两阶段训练策略。首先,将短时弛豫电压序列输入自动编码器进行无监督预训练。通过这一自动编码过程,编码器获得了在相同测试条件下对未标记的弛豫电压进行特征学习的能力。随后,通过冻结编码器权重和在解码器上执行迁移学习,将弛豫电压序列映射到相应的 V-Q 曲线,从而完成两阶段训练过程。在相同的历时下,与直接训练相比,所提出的方法实现了更先进的预测性能。这意味着使用 V-Q 曲线和推导出的增量容量曲线进行全面电池劣化监测的准确性更高。经过对来自不同实验室的 130 个电池样本的验证,所提出的方法能预测出高保真的 V-Q 曲线,均方根误差小于 0.03 Ah。这项研究强调了采用弛豫电压进行电池退化监测的能力,由于所需的弛豫时间较短,而且无需额外的循环信息,因此有望在非恒定电流充电情况下实现快速、全面的老化诊断。
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来源期刊
Etransportation
Etransportation Engineering-Automotive Engineering
CiteScore
19.80
自引率
12.60%
发文量
57
审稿时长
39 days
期刊介绍: eTransportation is a scholarly journal that aims to advance knowledge in the field of electric transportation. It focuses on all modes of transportation that utilize electricity as their primary source of energy, including electric vehicles, trains, ships, and aircraft. The journal covers all stages of research, development, and testing of new technologies, systems, and devices related to electrical transportation. The journal welcomes the use of simulation and analysis tools at the system, transport, or device level. Its primary emphasis is on the study of the electrical and electronic aspects of transportation systems. However, it also considers research on mechanical parts or subsystems of vehicles if there is a clear interaction with electrical or electronic equipment. Please note that this journal excludes other aspects such as sociological, political, regulatory, or environmental factors from its scope.
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