可解释性
人工神经网络
计算机科学
控制理论(社会学)
均方误差
电池(电)
荷电状态
适应性
人工智能
可扩展性
机器学习
卡尔曼滤波器
一般化
传递函数
过度拟合
稳健性(进化)
仿真
循环神经网络
工程类
系统标识
健康状况
近似误差
钛酸锂
算法
深度学习
扩展卡尔曼滤波器
推论
时域
可靠性(半导体)
作者
Seonri Hong,Hyejin Kim,Jonghoon Kim,Jongbok Baek
标识
DOI:10.1016/j.est.2026.120671
摘要
Accurate state of charge (SOC) estimation is essential to ensure the reliability and safety of battery management systems. Conventional data-driven methods rely on large labeled datasets and exhibit poor generalization across battery chemistries. By contrast, physics-based models offer interpretability but require complex parameter identification and incur high computational costs. To address these challenges, this study proposed a transfer learning-enhanced physics-informed neural network (TL-PINN) framework that combined the interpretability of physics-based models with the adaptability of deep learning. The framework integrated three key components: a physics-informed neural network for SOC estimation, a TL mechanism for domain adaptation, and a hybrid loss function that balances physical consistency and data efficiency. Experimental evaluations on the nickel manganese cobalt, lithium polymer, and nickel cobalt aluminum cells demonstrated that the TL-PINN outperformed conventional methods by achieving a lower root mean square error (RMSE), faster inference (approximately 2.4 ms), and enhanced robustness to sensor noise. Notably, under data-scarce conditions, the TL-PINN reduced the RMSE by more than 63% compared with the extended Kalman filter and more than 50% compared with recurrent neural network models. Furthermore, it consistently maintained a prediction error within 2%, even with noisy measurements. These results validate TL-PINN as a robust and scalable solution for SOC estimation under practical constraints and suggest its potential extension to broader battery health diagnostics, such as SOH and remaining useful life estimation. • A novel TL-PINN framework that integrates physical constraints with transfer learning for enhanced SOC estimation. • A cross-chemistry generalization study showing the model's ability to adapt to different battery types without retraining. • Evaluation under limited labeled data and noisy measurements, demonstrating superior data efficiency and noise robustness. • A comprehensive comparison with baseline models across various practical scenarios.
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