The Fourier-finite-element method with Nitsche-mortaring

Heinrich, Bernd, Jung, Beate

01 September 2006

The paper deals with a combination of the Fourier-finite-element method with the Nitsche-finite-element method (as a mortar method). The approach is applied to the Dirichlet problem of the Poisson equation in three-dimensional axisymmetric domains $\widehat\Omega$ with non-axisymmetric data. The approximating Fourier method yields a splitting of the 3D-problem into 2D-problems. For solving the 2D-problems on the meridian plane $\Omega_a$, the Nitsche-finite-element method with non-matching meshes is applied. Some important properties of the approximation scheme are derived and the rate of convergence in some $H^1$-like norm is proved to be of the type ${\mathcal O}(h+N^{-1})$ ($h$: mesh size on $\Omega_a$, $N$: length of the Fourier sum) in case of a regular solution of the boundary value problem. Finally, some numerical results are presented.

Fourier method

Nitsche-mortaring

non-matching meshes

ddc:510

Finite-Elemente-Methode

Mortar-Element-Methode

Poisson-Gleichung

Nitsche- and Fourier-finite-element method for the Poisson equation in axisymmetric domains with re-entrant edges

Heinrich, Bernd, Jung, Beate

11 September 2006

The paper deals with a combination of the Fourier method with the Nitsche-finite-element method (as a mortar method). The approach is applied to the Dirichlet problem of the Poisson equation in threedimensional axisymmetric domains with reentrant edges generating singularities. The approximating Fourier method yields a splitting of the 3D problem into 2D problems on the meridian plane of the given domain. For solving the 2D problems bearing corner singularities, the Nitsche finite-element method with non-matching meshes and mesh grading near reentrant corners is applied. Using the explicit representation of singular functions, the rate of convergence of the Fourier-Nitsche-mortaring is estimated in some $H^1$-like norm as well as in the $L_2$-norm. Finally, some numerical results are presented.

Fourier method

Nitsche-mortaring

non-matching meshes

ddc:510

Eckensingularität

Finite-Elemente-Methode

Poisson-Gleichung

Nitsche- and Fourier-finite-element method for the Poisson equation in axisymmetric domains with re-entrant edges

Heinrich, Bernd, Jung, Beate

11 September 2006

The paper deals with a combination of the Fourier method with the Nitsche-finite-element method (as a mortar method). The approach is applied to the Dirichlet problem of the Poisson equation in threedimensional axisymmetric domains with reentrant edges generating singularities. The approximating Fourier method yields a splitting of the 3D problem into 2D problems on the meridian plane of the given domain. For solving the 2D problems bearing corner singularities, the Nitsche finite-element method with non-matching meshes and mesh grading near reentrant corners is applied. Using the explicit representation of singular functions, the rate of convergence of the Fourier-Nitsche-mortaring is estimated in some $H^1$-like norm as well as in the $L_2$-norm. Finally, some numerical results are presented.

info:eu-repo/classification/ddc/510

ddc:510

Eckensingularität

Finite-Elemente-Methode

Poisson-Gleichung

Fourier method

Nitsche-mortaring

non-matching meshes

The Fourier-finite-element method with Nitsche-mortaring

Heinrich, Bernd, Jung, Beate

01 September 2006

The paper deals with a combination of the Fourier-finite-element method with the Nitsche-finite-element method (as a mortar method). The approach is applied to the Dirichlet problem of the Poisson equation in three-dimensional axisymmetric domains $\widehat\Omega$ with non-axisymmetric data. The approximating Fourier method yields a splitting of the 3D-problem into 2D-problems. For solving the 2D-problems on the meridian plane $\Omega_a$, the Nitsche-finite-element method with non-matching meshes is applied. Some important properties of the approximation scheme are derived and the rate of convergence in some $H^1$-like norm is proved to be of the type ${\mathcal O}(h+N^{-1})$ ($h$: mesh size on $\Omega_a$, $N$: length of the Fourier sum) in case of a regular solution of the boundary value problem. Finally, some numerical results are presented.

info:eu-repo/classification/ddc/510

ddc:510

Finite-Elemente-Methode

Mortar-Element-Methode

Poisson-Gleichung

Fourier method

Nitsche-mortaring

non-matching meshes