System Identification for Battery State Prediction and Lifespan Estimation

Q3 Engineering

IFAC-PapersOnLine Pub Date : 2024-01-01 DOI:10.1016/j.ifacol.2024.07.215

Chenyi Li, Long Zhang

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引用次数: 0

Abstract

In this paper, a nonlinear system Identification method, wavelet-network-based Nonlinear Auto-Regressive Exogenous (NLARX) approach, is employed for battery state estimation and lifespan estimation. More specifically, three key battery parameters and health metrics, including temperature, voltage and State of Charge (SOC), are estimated and these parameters are essential for condition or state monitoring. Further, State of Health (SOH), crucial for forecasting the battery remaining useful life, is also predicted. Two open datasets are used to train and validated the performance of the proposed method. For temperature and voltage forecasting, the NLARX model outperforms the existing Thermal Single Particle Model with electrolyte (TSPMe) for prediction horizons under 600 seconds. In SOC estimations, the NLARX method produces consistent 15-second ahead prediction results even only using a small percentage of training data, while the SOH estimation, the proposed metho provides precise SOH variation prediction for 400 post cycles with less than 10% of the batterys life for training. Extensive results demonstrates that the NLARX model’s promise for the precise prediction of key battery parameters and health metrics and it can be used as a useful tool for battery fault detection and remaining useful life prediction.

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电池状态预测和寿命估算的系统识别

本文采用了一种非线性系统识别方法，即基于小波网络的非线性自回归外生（NLARX）方法，用于电池状态估计和寿命估计。更具体地说，该方法估算了三个关键的电池参数和健康指标，包括温度、电压和充电状态 (SOC)，这些参数对于状态监控至关重要。此外，还能预测对预测电池剩余使用寿命至关重要的健康状态（SOH）。两个开放数据集用于训练和验证拟议方法的性能。在温度和电压预测方面，NLARX 模型在 600 秒以下的预测范围内优于现有的带电解液的热单粒子模型（TSPMe）。在 SOC 估算方面，即使只使用一小部分训练数据，NLARX 方法也能在 15 秒前得出一致的预测结果；而在 SOH 估算方面，建议的方法能在 400 个后循环中提供精确的 SOH 变化预测，而训练数据只占电池寿命的 10%。大量结果表明，NLARX 模型有望精确预测关键电池参数和健康指标，可用作电池故障检测和剩余使用寿命预测的有用工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IFAC-PapersOnLine Engineering-Control and Systems Engineering

CiteScore

1.70

自引率

0.00%

发文量

1122

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