过程(计算)
解算器
电池(电)
计算机科学
国家(计算机科学)
能量(信号处理)
人工神经网络
储能
工艺工程
控制工程
工程类
人工智能
算法
物理
操作系统
功率(物理)
程序设计语言
量子力学
作者
Yikai Jia,Xiong Shu,Han Jiang,Chunhao Yuan
标识
DOI:10.1021/acsenergylett.5c02530
摘要
The development of precise models for simulating rapidly expanding systems has become imperative for enhancing the planning and utilization of energy storage. It is often the case that traditional physical models are not suitable for use in calculations involving large or complex battery systems. This work proposes a neural battery model, which is developed by constructing a battery hidden-state dynamic process solver based on a neural network. The model overcomes the explicit dependence of conventional physics-driven approaches on model assumptions and governing equations. Instead, it employs a latent state space to uniformly characterize the internal dynamics. The implementation of dynamic process solving frameworks, such as neural ordinary differential equations (Neural ODEs), facilitates the establishment of a hidden-state dynamic system that ensures numerical stability and accuracy. Moreover, a battery network computational framework is proposed, which utilizes parallel computing to overcome the efficiency limitations of the model for large-scale battery packs.
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