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| Format: | Preprint |
| Veröffentlicht: |
2025
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| Online-Zugang: | https://arxiv.org/abs/2504.12938 |
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| _version_ | 1866909583187902464 |
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| author | Cao, Luling Sun, Weiwei |
| author_facet | Cao, Luling Sun, Weiwei |
| contents | This paper is concerned with non-uniform fully-mixed FEMs for dynamic coupled Stokes-Darcy model with the well-known Beavers-Joseph-Saffman (BJS) interface condition. In particular, a decoupled algorithm with the lowest-order mixed non-uniform FE approximations (MINI for the Stokes equation and RT0-DG0 for the Darcy equation) and the classical Nitsche-type penalty is studied. The method with the combined approximation of different orders is commonly used in practical simulations. However, the optimal error analysis of methods with non-uniform approximations for the coupled Stokes-Darcy flow model has remained challenging, although the analysis for uniform approximations has been well done. The key question is how the lower-order approximation to the Darcy flow influences the accuracy of the Stokes solution through the interface condition. In this paper, we prove that the decoupled algorithm provides a truly optimal convergence rate in L^2-norm in spatial direction: O(h^2) for Stokes velocity and O(h) for Darcy flow in the coupled Stokes-Darcy model. This implies that the lower-order approximation to the Darcy flow does not pollute the accuracy of numerical velocity for Stokes flow. The analysis presented in this paper is based on a well-designed Stokes-Darcy Ritz projection and given for a dynamic coupled model. The optimal error estimate holds for more general combined approximations and more general coupled models, including the corresponding model of steady-state Stokes-Darcy flows and the model of coupled dynamic Stokes and steady-state Darcy flows. Numerical results confirm our theoretical analysis and show that the decoupled algorithm is efficient. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2504_12938 |
| institution | arXiv |
| publishDate | 2025 |
| record_format | arxiv |
| spellingShingle | Optimal analysis of penalized lowest-order mixed FEMs for the Stokes-Darcy model Cao, Luling Sun, Weiwei Numerical Analysis This paper is concerned with non-uniform fully-mixed FEMs for dynamic coupled Stokes-Darcy model with the well-known Beavers-Joseph-Saffman (BJS) interface condition. In particular, a decoupled algorithm with the lowest-order mixed non-uniform FE approximations (MINI for the Stokes equation and RT0-DG0 for the Darcy equation) and the classical Nitsche-type penalty is studied. The method with the combined approximation of different orders is commonly used in practical simulations. However, the optimal error analysis of methods with non-uniform approximations for the coupled Stokes-Darcy flow model has remained challenging, although the analysis for uniform approximations has been well done. The key question is how the lower-order approximation to the Darcy flow influences the accuracy of the Stokes solution through the interface condition. In this paper, we prove that the decoupled algorithm provides a truly optimal convergence rate in L^2-norm in spatial direction: O(h^2) for Stokes velocity and O(h) for Darcy flow in the coupled Stokes-Darcy model. This implies that the lower-order approximation to the Darcy flow does not pollute the accuracy of numerical velocity for Stokes flow. The analysis presented in this paper is based on a well-designed Stokes-Darcy Ritz projection and given for a dynamic coupled model. The optimal error estimate holds for more general combined approximations and more general coupled models, including the corresponding model of steady-state Stokes-Darcy flows and the model of coupled dynamic Stokes and steady-state Darcy flows. Numerical results confirm our theoretical analysis and show that the decoupled algorithm is efficient. |
| title | Optimal analysis of penalized lowest-order mixed FEMs for the Stokes-Darcy model |
| topic | Numerical Analysis |
| url | https://arxiv.org/abs/2504.12938 |