Convergence analysis of coupling iterations for the unsteady transmission problem with mixed discretizations

Monge, Azahar; Birken, Philipp

Convergence analysis of coupling iterations for the unsteady transmission problem with mixed discretizations

Mark

Monge, Azahar ^LU and Birken, Philipp ^LU (2016) 7th European Congress on Computational Methods in Applied Sciences and Engineering, ECCOMAS Congress 2016 1. p.1530-1544

Abstract: We analyze the convergence rate of the Dirichlet-Neumann iteration for the fully discretized one dimensional unsteady transmission problem. Specifically, we consider the coupling of two linear heat equations on two identical non overlapping intervals. The Laplacian is discretized using finite differences on one interval and finite elements on the other and the implicit Euler method is used for the time discretization. Following previous analysis where finite elements where used on both subdomains, we provide an exact formula for the spectral radius of the iteration matrix for this specific mixed discretizations. We then show that these tend to the ratio of heat conductivities in the semidiscrete spatial limit, but to a factor of the... (More); We analyze the convergence rate of the Dirichlet-Neumann iteration for the fully discretized one dimensional unsteady transmission problem. Specifically, we consider the coupling of two linear heat equations on two identical non overlapping intervals. The Laplacian is discretized using finite differences on one interval and finite elements on the other and the implicit Euler method is used for the time discretization. Following previous analysis where finite elements where used on both subdomains, we provide an exact formula for the spectral radius of the iteration matrix for this specific mixed discretizations. We then show that these tend to the ratio of heat conductivities in the semidiscrete spatial limit, but to a factor of the ratio of the products of density and specific heat capacity in the semidiscrete temporal one. In the previous finite element analysis, the same result was obtained in the semidiscrete spatial limit but the factor in the temporal limit was lower. This explains the fast convergence previously observed for cases with strong jumps in the material coefficients. Numerical results confirm the analysis.
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Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/f6f5529f-8498-40de-8241-25e596c872d5

author

Monge, Azahar ^LU and Birken, Philipp ^LU

organization

Centre for Mathematical Sciences

publishing date

2016

type

Chapter in Book/Report/Conference proceeding

publication status

published

subject

Computational Mathematics

keywords

Coupled problems, Dirichlet-Neumann iteration, Fixed point iteration, Thermal fluid structure interaction, Transmission problem

host publication

ECCOMAS Congress 2016 - Proceedings of the 7th European Congress on Computational Methods in Applied Sciences and Engineering

volume

1

pages

15 pages

publisher

National Technical University of Athens

conference name

7th European Congress on Computational Methods in Applied Sciences and Engineering, ECCOMAS Congress 2016

conference location

Crete, Greece

conference dates

2016-06-05 - 2016-06-10

external identifiers

scopus:84995467062

ISBN

9786188284401

language

English

LU publication?

yes

id

f6f5529f-8498-40de-8241-25e596c872d5

date added to LUP

2017-04-24 15:20:19

date last changed

2022-01-30 19:45:48

@inproceedings{f6f5529f-8498-40de-8241-25e596c872d5,
  abstract     = {{<p>We analyze the convergence rate of the Dirichlet-Neumann iteration for the fully discretized one dimensional unsteady transmission problem. Specifically, we consider the coupling of two linear heat equations on two identical non overlapping intervals. The Laplacian is discretized using finite differences on one interval and finite elements on the other and the implicit Euler method is used for the time discretization. Following previous analysis where finite elements where used on both subdomains, we provide an exact formula for the spectral radius of the iteration matrix for this specific mixed discretizations. We then show that these tend to the ratio of heat conductivities in the semidiscrete spatial limit, but to a factor of the ratio of the products of density and specific heat capacity in the semidiscrete temporal one. In the previous finite element analysis, the same result was obtained in the semidiscrete spatial limit but the factor in the temporal limit was lower. This explains the fast convergence previously observed for cases with strong jumps in the material coefficients. Numerical results confirm the analysis.</p>}},
  author       = {{Monge, Azahar and Birken, Philipp}},
  booktitle    = {{ECCOMAS Congress 2016 - Proceedings of the 7th European Congress on Computational Methods in Applied Sciences and Engineering}},
  isbn         = {{9786188284401}},
  keywords     = {{Coupled problems; Dirichlet-Neumann iteration; Fixed point iteration; Thermal fluid structure interaction; Transmission problem}},
  language     = {{eng}},
  pages        = {{1530--1544}},
  publisher    = {{National Technical University of Athens}},
  title        = {{Convergence analysis of coupling iterations for the unsteady transmission problem with mixed discretizations}},
  volume       = {{1}},
  year         = {{2016}},
}

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Convergence analysis of coupling iterations for the unsteady transmission problem with mixed discretizations