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| + | ==Abstract== | ||
| + | We consider a hybrid approach for the approximation of the solution to parametric partial differential equations based on finite elements and deep neural networks. Finite element simulations with adaptive mesh refinement are used to generate input data for the training of a neural network. A deep feedforward neural network is then used to approximate the solution of the partial differential equation. We aim at balancing the numerical errors introduced by the finite element method and the neural network approximation respectively. Numerical results are presented for the transport equation. | ||
Revision as of 11:28, 24 May 2023
Abstract
We consider a hybrid approach for the approximation of the solution to parametric partial differential equations based on finite elements and deep neural networks. Finite element simulations with adaptive mesh refinement are used to generate input data for the training of a neural network. A deep feedforward neural network is then used to approximate the solution of the partial differential equation. We aim at balancing the numerical errors introduced by the finite element method and the neural network approximation respectively. Numerical results are presented for the transport equation.
Document information
Published on 24/05/23
Submitted on 24/05/23
Volume Error estimation (due to discretization and/or modeling), 2023
DOI: 10.23967/admos.2023.047
Licence: CC BY-NC-SA license
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