Guaranteed error bounds and local indicators for adaptive solvers using stabilised space-time IgA approximations to parabolic problems
Langer, U., Matculevich, S., & Repin, S. (2019). Guaranteed error bounds and local indicators for adaptive solvers using stabilised space-time IgA approximations to parabolic problems. Computers and Mathematics with Applications, 78(8), 2641-2671. https://doi.org/10.1016/j.camwa.2019.04.009
Published in
Computers and Mathematics with ApplicationsDate
2019Copyright
© 2019 Elsevier Ltd
The paper is concerned with space–time IgA approximations to parabolic initial–boundary value problems. We deduce guaranteed and fully computable error bounds adapted to special features of such type of approximations and investigate their efficiency. The derivation of error estimates is based on the analysis of the corresponding integral identity and exploits purely functional arguments in the maximal parabolic regularity setting. The estimates are valid for any approximation from the admissible (energy) class and do not contain mesh-dependent constants. They provide computable and fully guaranteed error bounds for the norms arising in stabilised space–time approximations. Furthermore, a posterior error estimates yield efficient error indicators enhancing the performance of adaptive solvers and generate very successful mesh refinement procedures. Theoretical results are verified with a series of numerical examples, in which approximate solutions and the corresponding fluxes are recovered by IgA techniques. The numerical results confirm the high efficiency of the method in the context of the two main goals of a posteriori error analysis: estimation of global errors and mesh adaptation.
...
Publisher
ElsevierISSN Search the Publication Forum
0898-1221Keywords
Publication in research information system
https://converis.jyu.fi/converis/portal/detail/Publication/30887731
Metadata
Show full item recordCollections
Additional information about funding
The research is supported by the Austrian Science Fund (FWF) through the NFN S117-03 project. This support is gratefully acknowledged. Furthermore, we appreciate the technical support and advises from Dr. Angelos Mantzaflaris, the main coordinator and developer of the open-source C++ library G+Smo that was used in our implementation and numerical tests. Last but not least, the authors would like to express their thanks to the anonymous referees for their helpful hints and valuable suggestions. ...License
Related items
Showing items with similar title or keywords.
-
Functional Type Error Control for Stabilised Space-Time IgA Approximations to Parabolic Problems
Langer, Ulrich; Matculevich, Svetlana; Repin, Sergey (Springer International Publishing, 2018)The paper is concerned with reliable space-time IgA schemes for parabolic initial-boundary value problems. We deduce a posteriori error estimates and investigate their applicability to space-time IgA approximations. ... -
Guaranteed and computable error bounds for approximations constructed by an iterative decoupling of the Biot problem
Kumar, Kundan; Kyas, Svetlana; Nordbotten, Jan Martin; Repin, Sergey (Elsevier, 2021)The paper is concerned with guaranteed a posteriori error estimates for a class of evolutionary problems related to poroelastic media governed by the quasi-static linear Biot equations. The system is decoupled by employing ... -
Guaranteed lower bounds for cost functionals of time-periodic parabolic optimization problems
Wolfmayr, Monika (Elsevier, 2020)In this paper, a new technique is shown for deriving computable, guaranteed lower bounds of functional type (minorants) for two different cost functionals subject to a parabolic time-periodic boundary value problem. Together ... -
Functional a posteriori error estimates for boundary element methods
Kurz, Stefan; Pauly, Dirk; Praetorius, Dirk; Repin, Sergey; Sebastian, Daniel (Springer, 2021)Functional error estimates are well-established tools for a posteriori error estimation and related adaptive mesh-refinement for the finite element method (FEM). The present work proposes a first functional error estimate ... -
A fast Fourier transform based direct solver for the Helmholtz problem
Toivanen, Jari; Wolfmayr, Monika (John Wiley & Sons, 2020)This article is devoted to the efficient numerical solution of the Helmholtz equation in a two‐ or three‐dimensional (2D or 3D) rectangular domain with an absorbing boundary condition (ABC). The Helmholtz problem is ...