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Geometric deep learning for computational mechanics Part I: anisotropic hyperelasticity

Vlassis, Nikolaos N. ; Ma, Ran ; Sun, WaiChing

Computer methods in applied mechanics and engineering, 2020-11, Vol.371, p.113299, Article 113299 [Periódico revisado por pares]

Amsterdam: Elsevier B.V

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  • Título:
    Geometric deep learning for computational mechanics Part I: anisotropic hyperelasticity
  • Autor: Vlassis, Nikolaos N. ; Ma, Ran ; Sun, WaiChing
  • Assuntos: Anisotropic energy functional ; Artificial intelligence ; Artificial neural networks ; Deep learning ; Energy ; Feature extraction ; Geometric machine learning ; Graph ; Internal energy ; Machine learning ; Microstructures ; Neural networks ; Norms ; Phase-field fracture ; Polycrystals ; Porosity ; Smoothness ; Topology ; Training
  • É parte de: Computer methods in applied mechanics and engineering, 2020-11, Vol.371, p.113299, Article 113299
  • Descrição: We present a machine learning approach that integrates geometric deep learning and Sobolev training to generate a family of finite strain anisotropic hyperelastic models that predict the homogenized responses of polycrystals previously unseen during the training. While hand-crafted hyperelasticity models often incorporate homogenized measures of microstructural attributes, such as the porosity or the averaged orientation of constituents, these measures may not adequately represent the topological structures of the attributes. We fill this knowledge gap by introducing the concept of the weighted graph as a new high-dimensional descriptor that represents topological information, such as the connectivity of anisotropic grains in an assemble. By leveraging a graph convolutional deep neural network in a hybrid machine learning architecture previously used in Frankel et al. (2019), the artificial intelligence extracts low-dimensional features from the weighted graphs and subsequently learns the influence of these low-dimensional features on the resultant stored elastic energy functionals. To ensure smoothness and prevent unintentionally generating a non-convex stored energy functional, we adopt the Sobolev training method for neural networks such that a stress measure is obtained implicitly by taking directional derivatives of the trained energy functional. Results from numerical experiments suggest that Sobolev training is capable of generating a hyperelastic energy functional that predicts both the elastic energy and stress measures more accurately than the classical training that minimizes L2 norms. Verification exercises against unseen benchmark FFT simulations and phase-field fracture simulations that employ the geometric learning generated elastic energy functional are conducted to demonstrate the quality of the predictions.
  • Editor: Amsterdam: Elsevier B.V
  • Idioma: Inglês
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  • Realização: ABCD-USP USP   Logos de Redes Sociais: Freepik

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