Deep learning from three-dimensional Lithium-ion battery multiphysics model Part II: Convolutional neural network and long short-term memory integration
IF 9.6 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
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引用次数: 0
Abstract
Lithium-ion (Li-ion) batteries have emerged as a cornerstone of electric vehicles (EVs), enabling the road transportation towards net zero. The success of electric vehicles largely hinges on the battery performance and safety. It is challenging to test and predict battery performance and safety issues by conventional methods, which are usually time-consuming and expensive, involving significant human and measurement errors. To enable the quick estimation of battery performance and safety, we developed three data-driven machine learning (ML) models, namely a convolutional neural network (CNN), a long short-term memory (LSTM), and a CNN-LSTM to predict battery discharge curves and local maximum temperature (hot spot) under various operating conditions. The developed ML models mitigated data scarcity by employing a three-dimensional multi-physics Li-ion battery model to generate enormous and diverse high-quality data. It was found the CNN-LSTM model outperforms the others and achieved high accuracy of 98.68% to learn discharge curves and battery maximum temperature, owing to the integration of spatial and sequential feature extraction. The battery safety can be improved by comparing the predicted maximum battery temperature against safe temperature threshold. The proposed data development and data-driven ML models are of great potential to provide digital tools for engineering high-performance and safe EVs.
锂离子(Li-ion)电池已成为电动汽车(EV)的基石,使道路交通实现零排放。电动汽车的成功在很大程度上取决于电池的性能和安全性。采用传统方法测试和预测电池性能和安全问题具有挑战性,因为传统方法通常耗时长、成本高,而且存在很大的人为误差和测量误差。为了快速评估电池性能和安全性,我们开发了三种数据驱动的机器学习(ML)模型,即卷积神经网络(CNN)、长短期记忆(LSTM)和 CNN-LSTM,用于预测各种工作条件下的电池放电曲线和局部最高温度(热点)。所开发的 ML 模型通过采用三维多物理场锂离子电池模型来生成大量多样的高质量数据,从而缓解了数据稀缺的问题。研究发现,CNN-LSTM 模型在学习放电曲线和电池最高温度方面优于其他模型,其准确率高达 98.68%,这得益于空间和序列特征提取的整合。通过比较预测的电池最高温度与安全温度阈值,可以提高电池的安全性。所提出的数据开发和数据驱动的 ML 模型具有巨大潜力,可为高性能和安全电动汽车的工程设计提供数字化工具。