Global and interior pointwise best approximationresults for the gradient of galerkin solutions for parabolic problems

Dmitriy Leykekhman; Boris Vexler

doi:10.1137/16M1080252

Global and interior pointwise best approximationresults for the gradient of galerkin solutions for parabolic problems

Dmitriy Leykekhman
, Boris Vexler

Chair of Optimal Control

University of Connecticut

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

In this paper we establish a best approximation property of fully discrete Galerkin solutions of second-order parabolic problems on convex polygonal and polyhedral domains in the L∞(I;W1; ∞ Ω) norm. The discretization method consists of continuous Lagrange finite elements in space and discontinuous Galerkin methods of arbitrary order in time. The method of the proof differs from the established fully discrete error estimate techniques and uses only elliptic results and discrete maximal parabolic regularity for discontinuous Galerkin methods established by the authors [D. Leykekhman and B. Vexler, Numer. Math., 135 (2017), pp. 923-952]. In addition, the proof does not require any relationship between spatial mesh sizes and time steps. We also establish an interior best approximation property that shows more local dependence of the error at a point.

Original language	English
Pages (from-to)	2025-2049
Number of pages	25
Journal	SIAM Journal on Numerical Analysis
Volume	55
Issue number	4
DOIs	https://doi.org/10.1137/16M1080252
State	Published - 2017

Keywords

Discontinuous Galerkin
Error estimates
Finite elements
Optimal control
Parabolic problems
Pointwise control
Pointwise error estimates

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10.1137/16M1080252

Cite this

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title = "Global and interior pointwise best approximationresults for the gradient of galerkin solutions for parabolic problems",

abstract = "In this paper we establish a best approximation property of fully discrete Galerkin solutions of second-order parabolic problems on convex polygonal and polyhedral domains in the L∞(I;W1; ∞ Ω) norm. The discretization method consists of continuous Lagrange finite elements in space and discontinuous Galerkin methods of arbitrary order in time. The method of the proof differs from the established fully discrete error estimate techniques and uses only elliptic results and discrete maximal parabolic regularity for discontinuous Galerkin methods established by the authors [D. Leykekhman and B. Vexler, Numer. Math., 135 (2017), pp. 923-952]. In addition, the proof does not require any relationship between spatial mesh sizes and time steps. We also establish an interior best approximation property that shows more local dependence of the error at a point.",

keywords = "Discontinuous Galerkin, Error estimates, Finite elements, Optimal control, Parabolic problems, Pointwise control, Pointwise error estimates",

author = "Dmitriy Leykekhman and Boris Vexler",

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year = "2017",

doi = "10.1137/16M1080252",

language = "English",

volume = "55",

pages = "2025--2049",

journal = "SIAM Journal on Numerical Analysis",

issn = "0036-1429",

publisher = "Society for Industrial and Applied Mathematics Publications",

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TY - JOUR

T1 - Global and interior pointwise best approximationresults for the gradient of galerkin solutions for parabolic problems

AU - Leykekhman, Dmitriy

AU - Vexler, Boris

PY - 2017

Y1 - 2017

N2 - In this paper we establish a best approximation property of fully discrete Galerkin solutions of second-order parabolic problems on convex polygonal and polyhedral domains in the L∞(I;W1; ∞ Ω) norm. The discretization method consists of continuous Lagrange finite elements in space and discontinuous Galerkin methods of arbitrary order in time. The method of the proof differs from the established fully discrete error estimate techniques and uses only elliptic results and discrete maximal parabolic regularity for discontinuous Galerkin methods established by the authors [D. Leykekhman and B. Vexler, Numer. Math., 135 (2017), pp. 923-952]. In addition, the proof does not require any relationship between spatial mesh sizes and time steps. We also establish an interior best approximation property that shows more local dependence of the error at a point.

AB - In this paper we establish a best approximation property of fully discrete Galerkin solutions of second-order parabolic problems on convex polygonal and polyhedral domains in the L∞(I;W1; ∞ Ω) norm. The discretization method consists of continuous Lagrange finite elements in space and discontinuous Galerkin methods of arbitrary order in time. The method of the proof differs from the established fully discrete error estimate techniques and uses only elliptic results and discrete maximal parabolic regularity for discontinuous Galerkin methods established by the authors [D. Leykekhman and B. Vexler, Numer. Math., 135 (2017), pp. 923-952]. In addition, the proof does not require any relationship between spatial mesh sizes and time steps. We also establish an interior best approximation property that shows more local dependence of the error at a point.

KW - Discontinuous Galerkin

KW - Error estimates

KW - Finite elements

KW - Optimal control

KW - Parabolic problems

KW - Pointwise control

KW - Pointwise error estimates

UR - https://www.scopus.com/pages/publications/85028631334

U2 - 10.1137/16M1080252

DO - 10.1137/16M1080252

M3 - Article

AN - SCOPUS:85028631334

SN - 0036-1429

VL - 55

SP - 2025

EP - 2049

JO - SIAM Journal on Numerical Analysis

JF - SIAM Journal on Numerical Analysis

IS - 4

ER -

Global and interior pointwise best approximationresults for the gradient of galerkin solutions for parabolic problems

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Keywords

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