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A new approach to constructing vector splitting schemes in mixed finite element method for parabolic problems. / Voronin, Kirill; Laevsky, Yuri.

в: Journal of Numerical Mathematics, Том 25, № 1, 01.03.2017, стр. 17-34.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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Voronin K, Laevsky Y. A new approach to constructing vector splitting schemes in mixed finite element method for parabolic problems. Journal of Numerical Mathematics. 2017 март 1;25(1):17-34. doi: 10.1515/jnma-2015-0076

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Voronin, Kirill ; Laevsky, Yuri. / A new approach to constructing vector splitting schemes in mixed finite element method for parabolic problems. в: Journal of Numerical Mathematics. 2017 ; Том 25, № 1. стр. 17-34.

BibTeX

@article{91804abd0c0e47fea19eb40e546239a2,
title = "A new approach to constructing vector splitting schemes in mixed finite element method for parabolic problems",
abstract = "A general setting for a new approach to constructing vector splitting schemes in mixed FEM for heat transfer problem is considered. For space approximation Raviart-Thomas finite elements of lowest order are implemented on rectangular (parallelepiped) mesh. The main question discussed is how to implement time discretization so as to obtain efficient numerical algorithms. The key idea of the proposed approach is to use scalar splitting schemes for heat flux divergence. This allows one to carry out accuracy and stability analysis on the basis of the well-known results for underlying scalar splitting schemes. A priori estimates are obtained for vector splitting schemes in two- and three-dimensional cases using the idea of flux decomposition onto divergence-free and potential components at discrete level. It is shown that splitting schemes which have been proposed by other approaches based on Uzawa algorithm's modification and block triangular factorization are included as special cases by an appropriate choice of the underlying splitting schemes for heat flux divergence. Generalization of the discussed approach is presented for second-order hyperbolic problems. Moreover, the general idea of using splitting schemes for the flux divergence to construct splitting schemes for fluxes can be easily extended to first-order hyperbolic systems, but by now several questions still remain unsolved.",
keywords = "a priori estimates, heat transfer, mixed finite element method, splitting schemes",
author = "Kirill Voronin and Yuri Laevsky",
year = "2017",
month = mar,
day = "1",
doi = "10.1515/jnma-2015-0076",
language = "English",
volume = "25",
pages = "17--34",
journal = "Journal of Numerical Mathematics",
issn = "1570-2820",
publisher = "Walter de Gruyter GmbH",
number = "1",

}

RIS

TY - JOUR

T1 - A new approach to constructing vector splitting schemes in mixed finite element method for parabolic problems

AU - Voronin, Kirill

AU - Laevsky, Yuri

PY - 2017/3/1

Y1 - 2017/3/1

N2 - A general setting for a new approach to constructing vector splitting schemes in mixed FEM for heat transfer problem is considered. For space approximation Raviart-Thomas finite elements of lowest order are implemented on rectangular (parallelepiped) mesh. The main question discussed is how to implement time discretization so as to obtain efficient numerical algorithms. The key idea of the proposed approach is to use scalar splitting schemes for heat flux divergence. This allows one to carry out accuracy and stability analysis on the basis of the well-known results for underlying scalar splitting schemes. A priori estimates are obtained for vector splitting schemes in two- and three-dimensional cases using the idea of flux decomposition onto divergence-free and potential components at discrete level. It is shown that splitting schemes which have been proposed by other approaches based on Uzawa algorithm's modification and block triangular factorization are included as special cases by an appropriate choice of the underlying splitting schemes for heat flux divergence. Generalization of the discussed approach is presented for second-order hyperbolic problems. Moreover, the general idea of using splitting schemes for the flux divergence to construct splitting schemes for fluxes can be easily extended to first-order hyperbolic systems, but by now several questions still remain unsolved.

AB - A general setting for a new approach to constructing vector splitting schemes in mixed FEM for heat transfer problem is considered. For space approximation Raviart-Thomas finite elements of lowest order are implemented on rectangular (parallelepiped) mesh. The main question discussed is how to implement time discretization so as to obtain efficient numerical algorithms. The key idea of the proposed approach is to use scalar splitting schemes for heat flux divergence. This allows one to carry out accuracy and stability analysis on the basis of the well-known results for underlying scalar splitting schemes. A priori estimates are obtained for vector splitting schemes in two- and three-dimensional cases using the idea of flux decomposition onto divergence-free and potential components at discrete level. It is shown that splitting schemes which have been proposed by other approaches based on Uzawa algorithm's modification and block triangular factorization are included as special cases by an appropriate choice of the underlying splitting schemes for heat flux divergence. Generalization of the discussed approach is presented for second-order hyperbolic problems. Moreover, the general idea of using splitting schemes for the flux divergence to construct splitting schemes for fluxes can be easily extended to first-order hyperbolic systems, but by now several questions still remain unsolved.

KW - a priori estimates

KW - heat transfer

KW - mixed finite element method

KW - splitting schemes

UR - http://www.scopus.com/inward/record.url?scp=85017651860&partnerID=8YFLogxK

U2 - 10.1515/jnma-2015-0076

DO - 10.1515/jnma-2015-0076

M3 - Article

AN - SCOPUS:85017651860

VL - 25

SP - 17

EP - 34

JO - Journal of Numerical Mathematics

JF - Journal of Numerical Mathematics

SN - 1570-2820

IS - 1

ER -

ID: 10264022