A Physics-Informed General Convolutional Network for the Computational Modeling of Materials with Damage

IF 2.6 3区工程技术 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Journal of Computing and Information Science in Engineering Pub Date : 2023-10-20 DOI:10.1115/1.4063863

Jake Janssen, Ghadir Haikal, Erin DeCarlo, Michael Hartnett, Matthew Kirby

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引用次数: 0

Abstract

Abstract Despite their effectiveness in modeling complex phenomena, the adoption of machine learning (ML) methods in computational mechanics has been hindered by the lack of availability of training datasets, limitations on accuracy of out-of-sample predictions, and computational cost. This work presents a physics-informed ML approach and network architecture that addresses these challenges in the context of modeling the behavior of materials with damage. The proposed methodology is a novel Physics-Informed General Convolutional Network (PIGCN) framework that features (1) the fusion of a dense edge network with a convolutional neural network (CNN) for specifying and enforcing boundary conditions and geometry information, (2) a data augmentation approach for learning more information from a static dataset that significantly reduces the necessary data for training, and (3) the use of a CNN for physics-informed ML applications, which is not as well explored as graph networks in the current literature. The PIGCN framework is demonstrated for a simple two-dimensional, rectangular plate with a hole or elliptical defect in a linear elastic material, but the approach is extensible to three dimensions and more complex problems. The results presented in the paper show that the PIGCN framework improves physics-based loss convergence and predictive capability compared to ML-only (physics-uninformed) architectures. A key outcome of this research is the significant reduction in training data requirements compared to ML-only models, which could reduce a considerable hurdle to using data-driven models in materials engineering where material experimental data is often limited.

查看原文本刊更多论文

基于物理信息的通用卷积网络损伤材料计算模型

尽管机器学习(ML)方法在模拟复杂现象方面很有效，但由于缺乏可用的训练数据集、样本外预测的准确性限制以及计算成本，机器学习(ML)方法在计算力学中的应用一直受到阻碍。这项工作提出了一种基于物理的机器学习方法和网络架构，解决了在对有损伤的材料的行为建模的背景下的这些挑战。提出的方法是一种新颖的基于物理的通用卷积网络(PIGCN)框架，其特点是(1)将密集边缘网络与卷积神经网络(CNN)融合，用于指定和执行边界条件和几何信息，(2)一种数据增强方法，用于从静态数据集中学习更多信息，从而显着减少训练所需的数据，以及(3)将CNN用于基于物理的ML应用程序。这在目前的文献中没有像图网络那样得到很好的探讨。PIGCN框架演示了线性弹性材料中一个简单的二维矩形板的孔或椭圆缺陷，但该方法可扩展到三维和更复杂的问题。论文中的结果表明，与纯ml(物理未知)架构相比，PIGCN框架提高了基于物理的损失收敛和预测能力。这项研究的一个关键成果是与纯机器学习模型相比，训练数据需求显著减少，这可以减少在材料工程中使用数据驱动模型的相当大的障碍，因为材料实验数据通常是有限的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Computing and Information Science in Engineering 工程技术-工程：制造

CiteScore

6.30

自引率

12.90%

发文量

100

审稿时长

6 months

期刊介绍： The ASME Journal of Computing and Information Science in Engineering (JCISE) publishes articles related to Algorithms, Computational Methods, Computing Infrastructure, Computer-Interpretable Representations, Human-Computer Interfaces, Information Science, and/or System Architectures that aim to improve some aspect of product and system lifecycle (e.g., design, manufacturing, operation, maintenance, disposal, recycling etc.). Applications considered in JCISE manuscripts should be relevant to the mechanical engineering discipline. Papers can be focused on fundamental research leading to new methods, or adaptation of existing methods for new applications. Scope: Advanced Computing Infrastructure; Artificial Intelligence; Big Data and Analytics; Collaborative Design; Computer Aided Design; Computer Aided Engineering; Computer Aided Manufacturing; Computational Foundations for Additive Manufacturing; Computational Foundations for Engineering Optimization; Computational Geometry; Computational Metrology; Computational Synthesis; Conceptual Design; Cybermanufacturing; Cyber Physical Security for Factories; Cyber Physical System Design and Operation; Data-Driven Engineering Applications; Engineering Informatics; Geometric Reasoning; GPU Computing for Design and Manufacturing; Human Computer Interfaces/Interactions; Industrial Internet of Things; Knowledge Engineering; Information Management; Inverse Methods for Engineering Applications; Machine Learning for Engineering Applications; Manufacturing Planning; Manufacturing Automation; Model-based Systems Engineering; Multiphysics Modeling and Simulation; Multiscale Modeling and Simulation; Multidisciplinary Optimization; Physics-Based Simulations; Process Modeling for Engineering Applications; Qualification, Verification and Validation of Computational Models; Symbolic Computing for Engineering Applications; Tolerance Modeling; Topology and Shape Optimization; Virtual and Augmented Reality Environments; Virtual Prototyping