Abstract
This paper presents a general Convolution Hierarchical Deep-learning Neural Networks (C-HiDeNN) computational framework for solving partial differential equations. This is the first paper of a series of papers devoted to C-HiDeNN. We focus on the theoretical foundation and formulation of the method. The C-HiDeNN framework provides a flexible way to construct high-order Cn approximation with arbitrary convergence rates and automatic mesh adaptivity. By constraining the C-HiDeNN to build certain functions, it can be degenerated to a specification, the so-called convolution finite element method (C-FEM). The C-FEM will be presented in detail and used to study the numerical performance of the convolution approximation. The C-FEM combines the standard C FE shape function and the meshfree-type radial basis interpolation. It has been demonstrated that the C-FEM can achieve arbitrary orders of smoothness and convergence rates by adjusting the different controlling parameters, such as the patch function dilation parameter and polynomial order, without increasing the degrees of freedom of the discretized systems, compared to FEM. We will also present the convolution tensor decomposition method under the reduced-order modeling setup. The proposed methods are expected to provide highly efficient solutions for extra-large scale problems while maintaining superior accuracy. The applications to transient heat transfer problems in additive manufacturing, topology optimization, GPU-based parallelization, and convolution isogeometric analysis have been discussed.
Original language | English (US) |
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Pages (from-to) | 333-362 |
Number of pages | 30 |
Journal | Computational Mechanics |
Volume | 72 |
Issue number | 2 |
DOIs | |
State | Published - Aug 2023 |
Funding
S. Tang and L. Zhang would like to thank the support of the National Natural Science Foundation of China (NSFC) under contract Nos. 11832001, 11988102, and 12202451.
Keywords
- Additive manufacturing
- Convolution FEM and HiDeNN
- High-order smoothness
- Isogeometric analysis (IGA)
- Reduced order modeling
- Tensor decomposition
ASJC Scopus subject areas
- Computational Mechanics
- Ocean Engineering
- Mechanical Engineering
- Computational Theory and Mathematics
- Computational Mathematics
- Applied Mathematics