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Dr. Barrios-Faundez, Tomas
Nombre de publicaciĂ³n
Dr. Barrios-Faundez, Tomas
Nombre completo
Barrios Faundez, Tomas Patricio
Facultad
Email
tomas@ucsc.cl
ORCID
2 results
Research Outputs
Now showing 1 - 2 of 2
- PublicationAnalysis of DG approximations for Stokes problem based on velocity-pseudostress formulation(Numerical Methods for Partial Differential Equations, 2017)
; ;Bustinza, RommelSĂ¡nchez, FelipeIn this article, we first discuss the well posedness of a modified LDG scheme of Stokes problem, considering a velocity-pseudostress formulation. The difficulty here relies on the fact that the application of classical BabuÅ¡ka-Brezzi theory is not easy, so we proceed in a nonstandard way. For uniqueness, we apply a discrete version of Fredholm's alternative theorem, while the a priori error analysis is done introducing suitable projections of exact solution. As a result, we prove that the method is convergent, and under suitable regularity assumptions on the exact solution, the optimal rate of convergence is guaranteed. Next, we explore two stabilizations to the previous scheme, by adding least squares type terms. For these cases, well posedness and the a priori error estimates are proved by the application of standard theory. We end this work with some numerical experiments considering our third scheme, whose results are in agreement with the theoretical properties we deduce. - PublicationAn a posteriori error analysis for an augmented discontinuous Galerkin method applied to Stokes problemThis paper deals with the a posteriori error analysis for an augmented mixed discontinuous formulation for the stationary Stokes problem. By considering an appropriate auxiliary problem, we derive an a posteriori error estimator. We prove that this estimator is reliable and locally efficient, and consists of just five residual terms. Numerical experiments confirm the theoretical properties of the augmented discontinuous scheme as well as of the estimator. They also show the capability of the corresponding adaptive algorithm to localize the singularities and the large stress regions of the solution.