对称强化神经网络在构造建模中的应用

IF 4.3 3区 工程技术 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Extreme Mechanics Letters Pub Date : 2024-07-01 DOI:10.1016/j.eml.2024.102188
Kévin Garanger , Julie Kraus , Julian J. Rimoli
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引用次数: 0

摘要

使用机器学习技术来均匀化任意微结构的有效行为已被证明不仅高效而且准确。在最近的一项工作中,我们展示了如何将最先进的微机械建模与先进的机器学习技术相结合,对表现出非线性和历史依赖行为的复杂微结构进行均质化(Logarzo 等人,2021 年)。由此产生的均质化模型被称为智能构造定律(SCL),可在有限元求解器中采用基于微结构的构造定律,其计算成本仅为传统多尺度并发方法的一小部分。在这项工作中,通过引入一种适用于各种神经网络架构、在神经元级别强制执行材料对称性的新方法,扩展了 SCL 的功能。这种方法利用神经网络中基于张量的特征,便于简洁、准确地表示对称性保持操作,而且具有足够的通用性,可扩展到构造建模以外的问题。本文详细介绍了这些基于张量的神经网络的构建及其在学习弹性和非弹性材料构成规律中的应用。通过对各种材料(包括各向同性新胡肯材料和张格格元材料)的全面测试,证明了这种方法在数据有限和强对称性的情况下优于传统神经网络。最后讨论了这种方法在发现材料对称性基础方面的潜力,并概述了未来的研究方向。
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Symmetry-enforcing neural networks with applications to constitutive modeling

The use of machine learning techniques to homogenize the effective behavior of arbitrary microstructures has been shown to be not only efficient but also accurate. In a recent work, we demonstrated how to combine state-of-the-art micromechanical modeling and advanced machine learning techniques to homogenize complex microstructures exhibiting non-linear and history dependent behaviors (Logarzo et al., 2021). The resulting homogenized model, termed smart constitutive law (SCL), enables the adoption of microstructurally informed constitutive laws into finite element solvers at a fraction of the computational cost required by traditional concurrent multiscale approaches. In this work, the capabilities of SCLs are expanded via the introduction of a novel methodology that enforces material symmetries at the neuron level, applicable across various neural network architectures. This approach utilizes tensor-based features in neural networks, facilitating the concise and accurate representation of symmetry-preserving operations, and is general enough to be extend to problems beyond constitutive modeling. Details on the construction of these tensor-based neural networks and their application in learning constitutive laws are presented for both elastic and inelastic materials. The superiority of this approach over traditional neural networks is demonstrated in scenarios with limited data and strong symmetries, through comprehensive testing on various materials, including isotropic neo-Hookean materials and tensegrity lattice metamaterials. This work is concluded by a discussion on the potential of this methodology to discover symmetry bases in materials and by an outline of future research directions.

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来源期刊
Extreme Mechanics Letters
Extreme Mechanics Letters Engineering-Mechanics of Materials
CiteScore
9.20
自引率
4.30%
发文量
179
审稿时长
45 days
期刊介绍: Extreme Mechanics Letters (EML) enables rapid communication of research that highlights the role of mechanics in multi-disciplinary areas across materials science, physics, chemistry, biology, medicine and engineering. Emphasis is on the impact, depth and originality of new concepts, methods and observations at the forefront of applied sciences.
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