Research article

Numerical solution of unsteady elastic equations with C-Bézier basis functions

  • Received: 16 August 2023 Revised: 23 October 2023 Accepted: 13 November 2023 Published: 04 December 2023
  • MSC : 65D18, 65M60

  • In this paper, the finite element method is applied to solve the unsteady elastic equations, C-Bézier basis functions are used to construct the shape function spaces, the semi-discrete scheme of the unsteady elastic equations is obtained by Galerkin finite element method and then the fully discretized Galerkin method is obtained by further discretizing the time variable with $ \theta $-scheme finite difference. Furthermore, for several numerical examples, the accuracy of approximate solutions are improved by 1–3 order-of magnitudes compared with the Lagrange basis function in $ L^\infty $ norm, $ L^2 $ norm and $ H^1 $ semi-norm, and the numerical examples show that the method proposed possesses a faster convergence rate. It is fully demonstrated that the C-Bézier basis functions have a better approximation effect in simulating unsteady elastic equations.

    Citation: Lanyin Sun, Kunkun Pang. Numerical solution of unsteady elastic equations with C-Bézier basis functions[J]. AIMS Mathematics, 2024, 9(1): 702-722. doi: 10.3934/math.2024036

    Related Papers:

  • In this paper, the finite element method is applied to solve the unsteady elastic equations, C-Bézier basis functions are used to construct the shape function spaces, the semi-discrete scheme of the unsteady elastic equations is obtained by Galerkin finite element method and then the fully discretized Galerkin method is obtained by further discretizing the time variable with $ \theta $-scheme finite difference. Furthermore, for several numerical examples, the accuracy of approximate solutions are improved by 1–3 order-of magnitudes compared with the Lagrange basis function in $ L^\infty $ norm, $ L^2 $ norm and $ H^1 $ semi-norm, and the numerical examples show that the method proposed possesses a faster convergence rate. It is fully demonstrated that the C-Bézier basis functions have a better approximation effect in simulating unsteady elastic equations.



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