Two-level a posteriori error estimation for adaptive multilevel stochastic Galerkin Finite Element Method

Alex Bespalov; Dirk Praetorius; Michele Ruggeri

doi:10.1137/20M1342586

Two-level a posteriori error estimation for adaptive multilevel stochastic Galerkin Finite Element Method

Alex Bespalov, Dirk Praetorius, Michele Ruggeri

Mathematics

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Abstract

The paper considers a class of parametric elliptic partial differential equations (PDEs), where the coefficients and the right-hand side function depend on infinitely many (uncertain) parameters. We introduce a two-level a posteriori estimator to control the energy error in multilevel stochastic Galerkin approximations for this class of PDE problems. We prove that the two-level estimator always provides a lower bound for the unknown approximation error, while the upper bound is equivalent to a saturation assumption. We propose and empirically compare three adaptive algorithms, where the structure of the estimator is exploited to perform spatial refinement as well as parametric enrichment. The paper also discusses implementation aspects of computing multilevel stochastic Galerkin approximations.

Original language	English
Pages (from-to)	1184-1216
Number of pages	33
Journal	SIAM/ASA Journal on Uncertainty Quantification
Volume	9
Issue number	3
DOIs	https://doi.org/10.1137/20M1342586
Publication status	Published - 16 Sept 2021

Keywords

a posteriori error analysis
adaptive methods
finite element method
multilevel stochastic Galerkin method
parametric PDEs
two-level error estimation

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BespalovA2021Two
This is the accepted manuscript for a forthcoming publication in SIAM/ASA Journal on Uncertainty Quantification.
Accepted author manuscript, 3.81 MBLicence: None: All rights reserved

Cite this

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title = "Two-level a posteriori error estimation for adaptive multilevel stochastic Galerkin Finite Element Method",

abstract = "The paper considers a class of parametric elliptic partial differential equations (PDEs), where the coefficients and the right-hand side function depend on infinitely many (uncertain) parameters. We introduce a two-level a posteriori estimator to control the energy error in multilevel stochastic Galerkin approximations for this class of PDE problems. We prove that the two-level estimator always provides a lower bound for the unknown approximation error, while the upper bound is equivalent to a saturation assumption. We propose and empirically compare three adaptive algorithms, where the structure of the estimator is exploited to perform spatial refinement as well as parametric enrichment. The paper also discusses implementation aspects of computing multilevel stochastic Galerkin approximations.",

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AU - Bespalov, Alex

AU - Praetorius, Dirk

AU - Ruggeri, Michele

PY - 2021/9/16

Y1 - 2021/9/16

N2 - The paper considers a class of parametric elliptic partial differential equations (PDEs), where the coefficients and the right-hand side function depend on infinitely many (uncertain) parameters. We introduce a two-level a posteriori estimator to control the energy error in multilevel stochastic Galerkin approximations for this class of PDE problems. We prove that the two-level estimator always provides a lower bound for the unknown approximation error, while the upper bound is equivalent to a saturation assumption. We propose and empirically compare three adaptive algorithms, where the structure of the estimator is exploited to perform spatial refinement as well as parametric enrichment. The paper also discusses implementation aspects of computing multilevel stochastic Galerkin approximations.

AB - The paper considers a class of parametric elliptic partial differential equations (PDEs), where the coefficients and the right-hand side function depend on infinitely many (uncertain) parameters. We introduce a two-level a posteriori estimator to control the energy error in multilevel stochastic Galerkin approximations for this class of PDE problems. We prove that the two-level estimator always provides a lower bound for the unknown approximation error, while the upper bound is equivalent to a saturation assumption. We propose and empirically compare three adaptive algorithms, where the structure of the estimator is exploited to perform spatial refinement as well as parametric enrichment. The paper also discusses implementation aspects of computing multilevel stochastic Galerkin approximations.

KW - a posteriori error analysis

KW - adaptive methods

KW - finite element method

KW - multilevel stochastic Galerkin method

KW - parametric PDEs

KW - two-level error estimation

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DO - 10.1137/20M1342586

M3 - Article

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JO - SIAM/ASA Journal on Uncertainty Quantification

JF - SIAM/ASA Journal on Uncertainty Quantification

IS - 3

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Two-level a posteriori error estimation for adaptive multilevel stochastic Galerkin Finite Element Method

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Keywords

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