人工神经网络
健康状况
计算机科学
均方误差
电池(电)
非线性系统
平均绝对误差
普遍性(动力系统)
控制理论(社会学)
一般化
稳健性(进化)
近似误差
功率(物理)
算法
人工智能
状态变量
估计理论
降级(电信)
国家(计算机科学)
绩效改进
工程类
电力系统
均方根
操作员(生物学)
变量(数学)
作者
Yingzhou Wang,Huaiwen Yu,Tianyi Ma,Yì Wáng,Xiuyu Zhang,Xinkai Chen
标识
DOI:10.1109/tie.2026.3654776
摘要
Accurate and reliable state of health (SOH) estimation is essential for the safe and stable operation of lithium-ion batteries. However, achieving highly accurate and robust SOH estimation remains challenging due to battery inconsistency, complex and variable working conditions, and the limited ability of models to characterize aging mechanisms. Thus, a deep physics-informed neural network method is proposed that integrates a self-attention mechanism with a Koopman neural operator (KNO) for SOH estimation of batteries. On the one hand, the self-attention mechanism enhances multidimensional health indicators, improving the model’s generalization ability. On the other hand, KNO solves the battery dynamic degradation equations, overcoming the challenges of long-term and complex nonlinear degradation estimation. Finally, the proposed method achieves reliable SOH estimation. Experimental results on the Northeast Electric Power University (NEEPU), Xi’an Jiaotong University (XJTU), and Tongji University (TJU) datasets show that the proposed method achieves the lowest mean absolute error of 0.0032, the mean absolute percentage error of 0.0036, and the root mean square error of 0.0043. The fitting coefficient is as high as 99.07%, representing a 47.25% improvement in performance compared to the existing PINN method. These results indicate the effectiveness and universality of the proposed method, providing a reliable solution for advanced battery health management.
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