利用物理增强神经网络对超弹性行为进行实验学习

Clément JailinLMPS, Antoine BenadyLMPS, Remi LegrouxLMPS, Emmanuel BarangerLMPS
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引用次数: 0

摘要

物理增强神经网络(PANN)的最新发展为材料行为建模提供了新的机遇。这些方法在对合成案例进行训练时已经证明了其效率。本研究旨在证明使用真实实验数据训练 PANN 对超弹性行为建模的有效性。该方法涉及两个配备了数字图像相关性和力传感器的单轴实验。试验的轴向变形超过 200%,并呈现非线性响应。从一次实验中提取的 20 个加载步骤用于训练 PANN。根据验证数据集的结果,利用六个加载步骤计算的平衡间隙损失,对模型结构进行了优化。最后,来自第一次实验的 544 个加载步骤和来自第二次独立实验的 80 个步骤被用于测试目的。PANN 模式有效地捕捉了训练载荷和训练载荷之外的超弹性行为,在使用各种评估指标进行评估时,与标准的 Neo-Hookean 模型相比表现出更优越的性能。利用实验力学数据训练 PANN 显示出了优于传统建模方法的良好效果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Experimental Learning of a Hyperelastic Behavior with a Physics-Augmented Neural Network
The recent development of Physics-Augmented Neural Networks (PANN) opens new opportunities for modeling material behaviors. These approaches have demonstrated their efficiency when trained on synthetic cases. This study aims to demonstrate the effectiveness of training PANN using real experimental data for modeling hyperelastic behavior. The approach involved two uni-axial experiments equipped with digital image correlation and force sensors. The tests achieved axial deformations exceeding 200% and presented non-linear responses. Twenty loading steps extracted from one experiment were used to train the PANN. The model architecture was optimized based on results from a validation dataset, utilizing equilibrium gap loss computed on six loading steps. Finally, 544 loading steps from the first experiment and 80 steps from a second independent experiment were used for testing purposes. The PANN model effectively captured the hyperelastic behavior across and beyond the training loads, showing superior performance compared to the standard Neo-Hookean model when assessed using various evaluation metrics. Training PANN with experimental mechanical data shows promising results, outperforming traditional modeling approaches.
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