Comprehensive performance comparison among different types of features in data-driven battery state of health estimation

TL;DR

This paper develops a physics-informed Gaussian process regression model for battery state of health estimation, demonstrating superior accuracy and robustness over other features and methods across extensive cycling data.

Contribution

It introduces a physics-informed GPR approach that outperforms other features and machine learning methods in battery SOH estimation, with high accuracy and generalization.

Findings

Physical features-based GPR achieves less than 1.1% error.

Physics-driven ML estimates more accurate SOH than non-physical features.

Method shows robustness across different data ratios and unseen conditions.

Abstract

Battery state of health (SOH), which informs the maximal available capacity of the battery, is a key indicator of battery aging failure. Accurately estimating battery SOH is a vital function of the battery management system that remains to be addressed. In this study, a physics-informed Gaussian process regression (GPR) model is developed for battery SOH estimation, with the performance being systematically compared with that of different types of features and machine learning (ML) methods. The method performance is validated based on 58826 cycling data units of 118 cells. Experimental results show that the physics-driven ML generally estimates more accurate SOH than other non-physical features under different scenarios. The physical features-based GPR predicts battery SOH with the errors being less than 1.1% based on 10 to 20 mins' relaxation data. And the high robustness and generalization capability of the methodology is also validated against different ratios of training and test data under unseen conditions. Results also highlight the more effective capability of knowledge transfer between different types of batteries with the physical features and GPR. This study demonstrates the excellence of physical features in indicating the state evolution of complex systems, and the improved indication performance of these features by combining a suitable ML method.