Abstract
We show that in the variational multiscale framework, the weak enforcement of essential boundary conditions via Nitsche's method corresponds directly to a particular choice of projection operator. The consistency, symmetry and penalty terms of Nitsche's method all originate from the fine-scale closure dictated by the corresponding scale decomposition. As a result of this formalism, we are able to determine the exact fine-scale contributions in Nitsche-type formulations. In the context of the advection–diffusion equation, we develop a residual-based model that incorporates the non-vanishing fine scales at the Dirichlet boundaries. This results in an additional boundary term with a new model parameter. We then propose a parameter estimation strategy for all parameters involved that is also consistent for higher-order basis functions. We illustrate with numerical experiments that our new augmented model mitigates the overly diffusive behavior that the classical residual-based fine-scale model exhibits in boundary layers at boundaries with weakly enforced essential conditions.
| Original language | English |
|---|---|
| Article number | 113878 |
| Number of pages | 26 |
| Journal | Computer Methods in Applied Mechanics and Engineering |
| Volume | 382 |
| DOIs | |
| Publication status | Published - 15 Aug 2021 |
Funding
D. Schillinger gratefully acknowledges support from the National Science Foundation via the NSF CAREER Award No. 1651577 and from the German Research Foundation (Deutsche Forschungsgemeinschaft DFG) via the Emmy Noether Award SCH 1249/2-1 . M.F.P. ten Eikelder and I. Akkerman are grateful for the support of Delft University of Technology .
Keywords
- Boundary layer accuracy
- Fine-scale Green's function
- Higher-order basis functions
- Nitsche's method
- Variational multiscale method
- Weak boundary conditions