Frame-independent vector-cloud neural network for nonlocal constitutive modeling on arbitrary grids

• Published in: Computer methods in applied mechanics and engineering Vol. 388; p. 114211
• Main Authors: Zhou, Xu-Hui, Han, Jiequn, Xiao, Heng
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier B.V 01.01.2022; Elsevier BV
• Subjects: Complex systems; Constitutive modeling; Constitutive models; Deep learning; First principles; Fluid dynamics; Fluid flow; Inverse modeling; Mathematical models; Modelling; Neural networks; Nonlocal closure model; Partial differential equations; Symmetry and invariance; Turbulence; Deep learning; Nonlocal closure model; Symmetry and invariance; Constitutive modeling; Inverse modeling
• ISSN: 0045-7825; 1879-2138
• DOI: 10.1016/j.cma.2021.114211

Constitutive models are widely used for modeling complex systems in science and engineering, where first-principle-based, well-resolved simulations are often prohibitively expensive. For example, in fluid dynamics, constitutive models are required to describe nonlocal, unresolved physics such as turbulence and laminar–turbulent transition. However, traditional constitutive models based on partial differential equations (PDEs) often lack robustness and are too rigid to accommodate diverse calibration datasets. We propose a frame-independent, nonlocal constitutive model based on a vector-cloud neural network that can be learned with data. The model predicts the closure variable at a point based on the flow information in its neighborhood. Such nonlocal information is represented by a group of points, each having a feature vector attached to it, and thus the input is referred to as vector cloud. The cloud is mapped to the closure variable through a frame-independent neural network, invariant both to coordinate translation and rotation and to the ordering of points in the cloud. As such, the network can deal with any number of arbitrarily arranged grid points and thus is suitable for unstructured meshes in fluid simulations. The merits of the proposed network are demonstrated for scalar transport PDEs on a family of parameterized periodic hill geometries. The vector-cloud neural network is a promising tool not only as nonlocal constitutive models and but also as general surrogate models for PDEs on irregular domains. •Proposed vector-cloud neural network for learning nonlocal constitutive models.•Preserved invariance to coordinate translation and rotation and to the ordering of points.•Suitable for unstructured meshes in practical applications with any number of arbitrarily arranged grid points.•Demonstrated predictive capability for transport PDEs on a parameterized periodic hill geometries.•The learned nonlocal relationship is consistent with physical intuition.