Convergence of Cell Based Finite Volume Discretizations for Problems of Control in the Conduction Coefficients

Research output: Contribution to journalJournal article – Annual report year: 2011Researchpeer-review

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Convergence of Cell Based Finite Volume Discretizations for Problems of Control in the Conduction Coefficients. / Evgrafov, Anton; Gregersen, Misha Marie; Sørensen, Mads Peter.

In: E S A I M: Mathematical Modelling and Numerical Analysis, Vol. 45, No. 6, 2011, p. 1059-1080.

Research output: Contribution to journalJournal article – Annual report year: 2011Researchpeer-review

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@article{23f13db5eb4e4466b0463b9551d1761e,
title = "Convergence of Cell Based Finite Volume Discretizations for Problems of Control in the Conduction Coefficients",
abstract = "We present a convergence analysis of a cell-based finite volume (FV) discretization scheme applied to a problem of control in the coefficients of a generalized Laplace equation modelling, for example, a steady state heat conduction. Such problems arise in applications dealing with geometric optimal design, in particular shape and topology optimization, and are most often solved numerically utilizing a finite element approach. Within the FV framework for control in the coefficients problems the main difficulty we face is the need to analyze the convergence of fluxes defined on the faces of cells, whereas the convergence of the coefficients happens only with respect to the {"}volumetric{"} Lebesgue measure. Additionally, depending on whether the stationarity conditions are stated for the discretized or the original continuous problem, two distinct concepts of stationarity at a discrete level arise. We provide characterizations of limit points, with respect to FV mesh size, of globally optimal solutions and two types of stationary points to the discretized problems. We illustrate the practical behaviour of our cell-based FV discretization algorithm on a numerical example.",
author = "Anton Evgrafov and Gregersen, {Misha Marie} and S{\o}rensen, {Mads Peter}",
note = "Copyright 2011 EDP Sciences.",
year = "2011",
doi = "10.1051/m2an/2011012",
language = "English",
volume = "45",
pages = "1059--1080",
journal = "E S A I M: M2AN",
issn = "0764-583X",
publisher = "E D P Sciences",
number = "6",

}

RIS

TY - JOUR

T1 - Convergence of Cell Based Finite Volume Discretizations for Problems of Control in the Conduction Coefficients

AU - Evgrafov, Anton

AU - Gregersen, Misha Marie

AU - Sørensen, Mads Peter

N1 - Copyright 2011 EDP Sciences.

PY - 2011

Y1 - 2011

N2 - We present a convergence analysis of a cell-based finite volume (FV) discretization scheme applied to a problem of control in the coefficients of a generalized Laplace equation modelling, for example, a steady state heat conduction. Such problems arise in applications dealing with geometric optimal design, in particular shape and topology optimization, and are most often solved numerically utilizing a finite element approach. Within the FV framework for control in the coefficients problems the main difficulty we face is the need to analyze the convergence of fluxes defined on the faces of cells, whereas the convergence of the coefficients happens only with respect to the "volumetric" Lebesgue measure. Additionally, depending on whether the stationarity conditions are stated for the discretized or the original continuous problem, two distinct concepts of stationarity at a discrete level arise. We provide characterizations of limit points, with respect to FV mesh size, of globally optimal solutions and two types of stationary points to the discretized problems. We illustrate the practical behaviour of our cell-based FV discretization algorithm on a numerical example.

AB - We present a convergence analysis of a cell-based finite volume (FV) discretization scheme applied to a problem of control in the coefficients of a generalized Laplace equation modelling, for example, a steady state heat conduction. Such problems arise in applications dealing with geometric optimal design, in particular shape and topology optimization, and are most often solved numerically utilizing a finite element approach. Within the FV framework for control in the coefficients problems the main difficulty we face is the need to analyze the convergence of fluxes defined on the faces of cells, whereas the convergence of the coefficients happens only with respect to the "volumetric" Lebesgue measure. Additionally, depending on whether the stationarity conditions are stated for the discretized or the original continuous problem, two distinct concepts of stationarity at a discrete level arise. We provide characterizations of limit points, with respect to FV mesh size, of globally optimal solutions and two types of stationary points to the discretized problems. We illustrate the practical behaviour of our cell-based FV discretization algorithm on a numerical example.

U2 - 10.1051/m2an/2011012

DO - 10.1051/m2an/2011012

M3 - Journal article

VL - 45

SP - 1059

EP - 1080

JO - E S A I M: M2AN

JF - E S A I M: M2AN

SN - 0764-583X

IS - 6

ER -