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Integrated computational environment for grid generation parallel technologies. / Il’in, Valery.

Parallel Computational Technologies - 14th International Conference, PCT 2020, Revised Selected Papers. ed. / Leonid Sokolinsky; Mikhail Zymbler. Springer Gabler, 2020. p. 58-68 (Communications in Computer and Information Science; Vol. 1263 CCIS).

Research output: Chapter in Book/Report/Conference proceedingConference contributionResearchpeer-review

Harvard

Il’in, V 2020, Integrated computational environment for grid generation parallel technologies. in L Sokolinsky & M Zymbler (eds), Parallel Computational Technologies - 14th International Conference, PCT 2020, Revised Selected Papers. Communications in Computer and Information Science, vol. 1263 CCIS, Springer Gabler, pp. 58-68, 14th International Scientific Conference on Parallel Computational Technologies, PCT 2020, Perm, Russian Federation, 27.05.2020. https://doi.org/10.1007/978-3-030-55326-5_5

APA

Il’in, V. (2020). Integrated computational environment for grid generation parallel technologies. In L. Sokolinsky, & M. Zymbler (Eds.), Parallel Computational Technologies - 14th International Conference, PCT 2020, Revised Selected Papers (pp. 58-68). (Communications in Computer and Information Science; Vol. 1263 CCIS). Springer Gabler. https://doi.org/10.1007/978-3-030-55326-5_5

Vancouver

Il’in V. Integrated computational environment for grid generation parallel technologies. In Sokolinsky L, Zymbler M, editors, Parallel Computational Technologies - 14th International Conference, PCT 2020, Revised Selected Papers. Springer Gabler. 2020. p. 58-68. (Communications in Computer and Information Science). doi: 10.1007/978-3-030-55326-5_5

Author

Il’in, Valery. / Integrated computational environment for grid generation parallel technologies. Parallel Computational Technologies - 14th International Conference, PCT 2020, Revised Selected Papers. editor / Leonid Sokolinsky ; Mikhail Zymbler. Springer Gabler, 2020. pp. 58-68 (Communications in Computer and Information Science).

BibTeX

@inproceedings{b3f3b947cfb147aa9826b0e7d6305a20,
title = "Integrated computational environment for grid generation parallel technologies",
abstract = "This paper is devoted to the conception and general structure of the integrated computational environment for constructing multi-dimensional large grids (with 1010 nodes and more) for high-performance solutions of interdisciplinary direct and inverse mathematical modelling problems in computational domains with complicated geometrical boundaries and contrast material properties. This includes direct and inverse statements which are described by the system of differential and/or integral equations. The constructed computational grid domain consists of subdomains featuring a grid, which may be of different types (structured or non-structured); discretization at the internal boundaries can be consistent or non-consistent. The methodology of such quasi-structured meshes makes it possible to use various algorithms and codes in the subdomains, as well as different data structure formats and their conversion. The proposed technologies include grid quality control, the generation of dynamic grids adapted to singularities of input geometric data of structures and multigrid approaches with local refinements, taking into account information about the solution to be obtained. The balanced grid domain decomposition, based on hybrid programming at the heterogeneous clusters with distributed and hierarchical shared memory, supports scalable parallelization. In addition, the paper outlines the technological requirements to provide a successful long-life cycle for the proposed computational environment. In a sense, the considered development presents a stable software ecosystem (integrated grid generator DELAUNAY) for supercomputing modelling in the epoch of big data and artificial intellect.",
keywords = "Adaptive quasi-structured grids, Data structures, Grid computational domain, Grid generation methods, Multi-dimensional boundary value problems, Scalable parallelization",
author = "Valery Il{\textquoteright}in",
note = "Publisher Copyright: {\textcopyright} Springer Nature Switzerland AG 2020.; 14th International Scientific Conference on Parallel Computational Technologies, PCT 2020 ; Conference date: 27-05-2020 Through 29-05-2020",
year = "2020",
month = jan,
day = "1",
doi = "10.1007/978-3-030-55326-5_5",
language = "English",
isbn = "9783030553258",
series = "Communications in Computer and Information Science",
publisher = "Springer Gabler",
pages = "58--68",
editor = "Leonid Sokolinsky and Mikhail Zymbler",
booktitle = "Parallel Computational Technologies - 14th International Conference, PCT 2020, Revised Selected Papers",
address = "Germany",

}

RIS

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T1 - Integrated computational environment for grid generation parallel technologies

AU - Il’in, Valery

N1 - Publisher Copyright: © Springer Nature Switzerland AG 2020.

PY - 2020/1/1

Y1 - 2020/1/1

N2 - This paper is devoted to the conception and general structure of the integrated computational environment for constructing multi-dimensional large grids (with 1010 nodes and more) for high-performance solutions of interdisciplinary direct and inverse mathematical modelling problems in computational domains with complicated geometrical boundaries and contrast material properties. This includes direct and inverse statements which are described by the system of differential and/or integral equations. The constructed computational grid domain consists of subdomains featuring a grid, which may be of different types (structured or non-structured); discretization at the internal boundaries can be consistent or non-consistent. The methodology of such quasi-structured meshes makes it possible to use various algorithms and codes in the subdomains, as well as different data structure formats and their conversion. The proposed technologies include grid quality control, the generation of dynamic grids adapted to singularities of input geometric data of structures and multigrid approaches with local refinements, taking into account information about the solution to be obtained. The balanced grid domain decomposition, based on hybrid programming at the heterogeneous clusters with distributed and hierarchical shared memory, supports scalable parallelization. In addition, the paper outlines the technological requirements to provide a successful long-life cycle for the proposed computational environment. In a sense, the considered development presents a stable software ecosystem (integrated grid generator DELAUNAY) for supercomputing modelling in the epoch of big data and artificial intellect.

AB - This paper is devoted to the conception and general structure of the integrated computational environment for constructing multi-dimensional large grids (with 1010 nodes and more) for high-performance solutions of interdisciplinary direct and inverse mathematical modelling problems in computational domains with complicated geometrical boundaries and contrast material properties. This includes direct and inverse statements which are described by the system of differential and/or integral equations. The constructed computational grid domain consists of subdomains featuring a grid, which may be of different types (structured or non-structured); discretization at the internal boundaries can be consistent or non-consistent. The methodology of such quasi-structured meshes makes it possible to use various algorithms and codes in the subdomains, as well as different data structure formats and their conversion. The proposed technologies include grid quality control, the generation of dynamic grids adapted to singularities of input geometric data of structures and multigrid approaches with local refinements, taking into account information about the solution to be obtained. The balanced grid domain decomposition, based on hybrid programming at the heterogeneous clusters with distributed and hierarchical shared memory, supports scalable parallelization. In addition, the paper outlines the technological requirements to provide a successful long-life cycle for the proposed computational environment. In a sense, the considered development presents a stable software ecosystem (integrated grid generator DELAUNAY) for supercomputing modelling in the epoch of big data and artificial intellect.

KW - Adaptive quasi-structured grids

KW - Data structures

KW - Grid computational domain

KW - Grid generation methods

KW - Multi-dimensional boundary value problems

KW - Scalable parallelization

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U2 - 10.1007/978-3-030-55326-5_5

DO - 10.1007/978-3-030-55326-5_5

M3 - Conference contribution

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SN - 9783030553258

T3 - Communications in Computer and Information Science

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EP - 68

BT - Parallel Computational Technologies - 14th International Conference, PCT 2020, Revised Selected Papers

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A2 - Zymbler, Mikhail

PB - Springer Gabler

T2 - 14th International Scientific Conference on Parallel Computational Technologies, PCT 2020

Y2 - 27 May 2020 through 29 May 2020

ER -

ID: 24954780