Parallel implementations of a finite element formulation for fluid-structure interactions in interior flows

S. E. Ray; G. P. Wren; T. E. Tezduyar

doi:10.1016/s0167-8191(97)00053-7

Parallel implementations of a finite element formulation for fluid-structure interactions in interior flows

S. E. Ray, G. P. Wren^*, T. E. Tezduyar

^*この研究の対応する著者

研究成果: Article › 査読

17 被引用数 (Scopus)

抄録

In this paper, shared-memory parallel implementations of a finite element formulation for unsteady interior flows with fluid-structure interactions are presented. The parallel computing platforms targeted are the CRAY C90, the Silicon Graphics (SGI) ONYX and the SGI Power Challenge. The formulation is based on the stabilized space-time finite element method developed earlier for a more general class of flow problems involving moving boundaries and interfaces. The specific test problem used in the performance evaluations involves fluid-structure interactions between a barotropic working fluid and one of the two pistons surrounding this fluid. We demonstrate that advanced formulations applicable to complex problems can be implemented in a parallel computing environment without resulting in a significant distraction from the scientific objectives of solving such complex problems.

本文言語	English
ページ（範囲）	1279-1292
ページ数	14
ジャーナル	Parallel Computing
巻	23
号	9
DOI	https://doi.org/10.1016/s0167-8191(97)00053-7
出版ステータス	Published - 1997 9月
外部発表	はい

ASJC Scopus subject areas

ソフトウェア
理論的コンピュータサイエンス
ハードウェアとアーキテクチャ
コンピュータネットワークおよび通信
コンピュータグラフィックスおよびコンピュータ支援設計
人工知能

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10.1016/s0167-8191(97)00053-7

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title = "Parallel implementations of a finite element formulation for fluid-structure interactions in interior flows",

abstract = "In this paper, shared-memory parallel implementations of a finite element formulation for unsteady interior flows with fluid-structure interactions are presented. The parallel computing platforms targeted are the CRAY C90, the Silicon Graphics (SGI) ONYX and the SGI Power Challenge. The formulation is based on the stabilized space-time finite element method developed earlier for a more general class of flow problems involving moving boundaries and interfaces. The specific test problem used in the performance evaluations involves fluid-structure interactions between a barotropic working fluid and one of the two pistons surrounding this fluid. We demonstrate that advanced formulations applicable to complex problems can be implemented in a parallel computing environment without resulting in a significant distraction from the scientific objectives of solving such complex problems.",

keywords = "Finite elements, Fluid-structure interactions, Interior flows, Shared-memory multiprocessors",

author = "Ray, {S. E.} and Wren, {G. P.} and Tezduyar, {T. E.}",

note = "Funding Information: {\textquoteright} Corresponding author. Tel.: + l-410-2786199, fax: + I-410-2786159; e-mail: wten@arl.mil. {\textquoteright} This research was sponsored by ARPA under NJST contract 6ONANB2D1272 and by the Army High Performance Computing Research Center under the auspices of the Department of the Army, Army Research Laboratory cooperative agreement number DAAHO4-95-24003/connact number DAAHOC95-C-0008, the content of which does not necessarily reflect the position or the policy of the government. and no official endorsement should be inftxrcd. CRAY C90 time was provided in part by the University of Minnesota Supercomputer Institute. We are thankful to Dr. Vinay Kalro of the University of Minnesota for his valuable comments on parallel implementations.",

year = "1997",

month = sep,

doi = "10.1016/s0167-8191(97)00053-7",

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pages = "1279--1292",

journal = "Parallel Computing",

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AU - Wren, G. P.

AU - Tezduyar, T. E.

N1 - Funding Information: ’ Corresponding author. Tel.: + l-410-2786199, fax: + I-410-2786159; e-mail: wten@arl.mil. ’ This research was sponsored by ARPA under NJST contract 6ONANB2D1272 and by the Army High Performance Computing Research Center under the auspices of the Department of the Army, Army Research Laboratory cooperative agreement number DAAHO4-95-24003/connact number DAAHOC95-C-0008, the content of which does not necessarily reflect the position or the policy of the government. and no official endorsement should be inftxrcd. CRAY C90 time was provided in part by the University of Minnesota Supercomputer Institute. We are thankful to Dr. Vinay Kalro of the University of Minnesota for his valuable comments on parallel implementations.

PY - 1997/9

Y1 - 1997/9

N2 - In this paper, shared-memory parallel implementations of a finite element formulation for unsteady interior flows with fluid-structure interactions are presented. The parallel computing platforms targeted are the CRAY C90, the Silicon Graphics (SGI) ONYX and the SGI Power Challenge. The formulation is based on the stabilized space-time finite element method developed earlier for a more general class of flow problems involving moving boundaries and interfaces. The specific test problem used in the performance evaluations involves fluid-structure interactions between a barotropic working fluid and one of the two pistons surrounding this fluid. We demonstrate that advanced formulations applicable to complex problems can be implemented in a parallel computing environment without resulting in a significant distraction from the scientific objectives of solving such complex problems.

AB - In this paper, shared-memory parallel implementations of a finite element formulation for unsteady interior flows with fluid-structure interactions are presented. The parallel computing platforms targeted are the CRAY C90, the Silicon Graphics (SGI) ONYX and the SGI Power Challenge. The formulation is based on the stabilized space-time finite element method developed earlier for a more general class of flow problems involving moving boundaries and interfaces. The specific test problem used in the performance evaluations involves fluid-structure interactions between a barotropic working fluid and one of the two pistons surrounding this fluid. We demonstrate that advanced formulations applicable to complex problems can be implemented in a parallel computing environment without resulting in a significant distraction from the scientific objectives of solving such complex problems.

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KW - Shared-memory multiprocessors

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Parallel implementations of a finite element formulation for fluid-structure interactions in interior flows

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