Adaptive finite element methods for an optimal control problem involving Dirac measures

Alejandro Allendes; Enrique Otárola; Richard Rankin; Abner J. Salgado

doi:10.1007/s00211-017-0867-9

Adaptive finite element methods for an optimal control problem involving Dirac measures

Alejandro Allendes, Enrique Otárola, Richard Rankin, Abner J. Salgado

Research output: Journal Publication › Article › peer-review

16 Citations (Scopus)

Abstract

The purpose of this work is the design and analysis of a reliable and efficient a posteriori error estimator for the so-called pointwise tracking optimal control problem. This linear-quadratic optimal control problem entails the minimization of a cost functional that involves point evaluations of the state, thus leading to an adjoint problem with Dirac measures on the right hand side; control constraints are also considered. The proposed error estimator relies on a posteriori error estimates in the maximum norm for the state and in Muckenhoupt weighted Sobolev spaces for the adjoint state. We present an analysis that is valid for two and three-dimensional domains. We conclude by presenting several numerical experiments which reveal the competitive performance of adaptive methods based on the devised error estimator.

Original language	English
Pages (from-to)	159-197
Number of pages	39
Journal	Numerische Mathematik
Volume	137
Issue number	1
DOIs	https://doi.org/10.1007/s00211-017-0867-9
Publication status	Published - 1 Sept 2017
Externally published	Yes

Keywords

A posteriori error analysis
Adaptive finite elements
Dirac measures
Maximum norm
Muckenhoupt weights
Pointwise tracking optimal control problem
Weighted Sobolev spaces

ASJC Scopus subject areas

Computational Mathematics
Applied Mathematics

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10.1007/s00211-017-0867-9

Cite this

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abstract = "The purpose of this work is the design and analysis of a reliable and efficient a posteriori error estimator for the so-called pointwise tracking optimal control problem. This linear-quadratic optimal control problem entails the minimization of a cost functional that involves point evaluations of the state, thus leading to an adjoint problem with Dirac measures on the right hand side; control constraints are also considered. The proposed error estimator relies on a posteriori error estimates in the maximum norm for the state and in Muckenhoupt weighted Sobolev spaces for the adjoint state. We present an analysis that is valid for two and three-dimensional domains. We conclude by presenting several numerical experiments which reveal the competitive performance of adaptive methods based on the devised error estimator.",

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T1 - Adaptive finite element methods for an optimal control problem involving Dirac measures

AU - Allendes, Alejandro

AU - Otárola, Enrique

AU - Rankin, Richard

AU - Salgado, Abner J.

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Y1 - 2017/9/1

N2 - The purpose of this work is the design and analysis of a reliable and efficient a posteriori error estimator for the so-called pointwise tracking optimal control problem. This linear-quadratic optimal control problem entails the minimization of a cost functional that involves point evaluations of the state, thus leading to an adjoint problem with Dirac measures on the right hand side; control constraints are also considered. The proposed error estimator relies on a posteriori error estimates in the maximum norm for the state and in Muckenhoupt weighted Sobolev spaces for the adjoint state. We present an analysis that is valid for two and three-dimensional domains. We conclude by presenting several numerical experiments which reveal the competitive performance of adaptive methods based on the devised error estimator.

AB - The purpose of this work is the design and analysis of a reliable and efficient a posteriori error estimator for the so-called pointwise tracking optimal control problem. This linear-quadratic optimal control problem entails the minimization of a cost functional that involves point evaluations of the state, thus leading to an adjoint problem with Dirac measures on the right hand side; control constraints are also considered. The proposed error estimator relies on a posteriori error estimates in the maximum norm for the state and in Muckenhoupt weighted Sobolev spaces for the adjoint state. We present an analysis that is valid for two and three-dimensional domains. We conclude by presenting several numerical experiments which reveal the competitive performance of adaptive methods based on the devised error estimator.

KW - A posteriori error analysis

KW - Adaptive finite elements

KW - Dirac measures

KW - Maximum norm

KW - Muckenhoupt weights

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KW - Weighted Sobolev spaces

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Adaptive finite element methods for an optimal control problem involving Dirac measures

Abstract

Keywords

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