Spatial-temporal Attention-Based Time Series Prediction Network for Lithium Battery Remaining Useful Life Estimation

• Published in: 2024 4th International Conference on Neural Networks, Information and Communication (NNICE) pp. 91 - 94
• Main Authors: Bao, Zhengyi, Lin, Huipin, Guan, Siwei, Zheng, Xiaorong, Li, Zhi, Gao, Mingyu
• Format: Conference Proceeding
• Language: English
• Published: IEEE 19.01.2024
• Subjects: Battery management systems; Correlation; Feature extraction; Gate Recurrent Unit; Life estimation; Lithium Battery; NASA; Predictive models; Remaining Useful Life; Spatio-temporal Attention; Time series analysis
• DOI: 10.1109/NNICE61279.2024.10498716

The accurate estimation of the remaining useful life (RUL) of lithium batteries is a pivotal aspect in battery management systems, essential for efficient battery management, optimization of battery performance, and enhanced user experience. Presently, prevailing deep learning methods for battery RUL estimation mainly focus on individual neural networks, overlooking the crucial spatial-temporal characteristics. In this study, we introduce a time series prediction framework employing a gate recurrent unit (GRU) in tandem with a spatial-temporal attention mechanism. Our methodology involves initially screening data associated with high correlation to battery capacity through correlation coefficient analysis. This screened data is then processed by a series of GRU network layers to model the relationship between battery input and capacity. Following this, the extracted features undergo a deeper level analysis, whereby a spatial-temporal attention mechanism assigns varying weights to these features in the temporal and spatial dimensions to capture correlations more intricately. We evaluated the proposed method on the NASA dataset, and the experimental findings validate that our network achieves accurate time series predictions with an MAE of less than 1.5%.