Spatial adaptive sampling in multiscale simulation

Bertrand Rouet-Leduc; Kipton Barros; Emmanuel Cieren; Venmugil Elango; Christoph Junghans; Turab Lookman; Jamaludin Mohd-Yusof; Robert S. Pavel; Axel Y. Rivera; Dominic Roehm; Allen L. McPherson; Timothy C. Germann

doi:10.1016/j.cpc.2014.03.011

Spatial adaptive sampling in multiscale simulation

Bertrand Rouet-Leduc
, Kipton Barros
, Emmanuel Cieren
, Venmugil Elango
, Christoph Junghans
, Turab Lookman
, Jamaludin Mohd-Yusof
, Robert S. Pavel
, Axel Y. Rivera
, Dominic Roehm
, Allen L. McPherson
, Timothy C. Germann

Los Alamos National Laboratory Theoretical Division
University of Cambridge
Commissariat à l’énergie atomique et aux énergies alternatives
Computational Earth Science, Earth and Environmental Sciences Division, Los Alamos National Laboratory
Ohio State University
University of Delaware
University of Utah
University of Stuttgart

Research output: Contribution to journal › Article › peer-review

21 Scopus citations

Abstract

In a common approach to multiscale simulation, an incomplete set of macroscale equations must be supplemented with constitutive data provided by fine-scale simulation. Collecting statistics from these fine-scale simulations is typically the overwhelming computational cost. We reduce this cost by interpolating the results of fine-scale simulation over the spatial domain of the macro-solver. Unlike previous adaptive sampling strategies, we do not interpolate on the potentially very high dimensional space of inputs to the fine-scale simulation. Our approach is local in space and time, avoids the need for a central database, and is designed to parallelize well on large computer clusters. To demonstrate our method, we simulate one-dimensional elastodynamic shock propagation using the Heterogeneous Multiscale Method (HMM); we find that spatial adaptive sampling requires only ≈50×^N0.14 fine-scale simulations to reconstruct the stress field at all N grid points. Related multiscale approaches, such as Equation Free methods, may also benefit from spatial adaptive sampling.

Original language	English
Pages (from-to)	1857-1864
Number of pages	8
Journal	Computer Physics Communications
Volume	185
Issue number	7
DOIs	https://doi.org/10.1016/j.cpc.2014.03.011
State	Published - Jul 2014
Externally published	Yes

Keywords

Adaptive sampling
Multiscale

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10.1016/j.cpc.2014.03.011

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@article{df2ea233dec2470791c595414b5723aa,

title = "Spatial adaptive sampling in multiscale simulation",

abstract = "In a common approach to multiscale simulation, an incomplete set of macroscale equations must be supplemented with constitutive data provided by fine-scale simulation. Collecting statistics from these fine-scale simulations is typically the overwhelming computational cost. We reduce this cost by interpolating the results of fine-scale simulation over the spatial domain of the macro-solver. Unlike previous adaptive sampling strategies, we do not interpolate on the potentially very high dimensional space of inputs to the fine-scale simulation. Our approach is local in space and time, avoids the need for a central database, and is designed to parallelize well on large computer clusters. To demonstrate our method, we simulate one-dimensional elastodynamic shock propagation using the Heterogeneous Multiscale Method (HMM); we find that spatial adaptive sampling requires only ≈50×N0.14 fine-scale simulations to reconstruct the stress field at all N grid points. Related multiscale approaches, such as Equation Free methods, may also benefit from spatial adaptive sampling.",

keywords = "Adaptive sampling, Multiscale",

author = "Bertrand Rouet-Leduc and Kipton Barros and Emmanuel Cieren and Venmugil Elango and Christoph Junghans and Turab Lookman and Jamaludin Mohd-Yusof and Pavel, \{Robert S.\} and Rivera, \{Axel Y.\} and Dominic Roehm and McPherson, \{Allen L.\} and Germann, \{Timothy C.\}",

year = "2014",

month = jul,

doi = "10.1016/j.cpc.2014.03.011",

language = "英语",

volume = "185",

pages = "1857--1864",

journal = "Computer Physics Communications",

issn = "0010-4655",

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TY - JOUR

T1 - Spatial adaptive sampling in multiscale simulation

AU - Rouet-Leduc, Bertrand

AU - Barros, Kipton

AU - Cieren, Emmanuel

AU - Elango, Venmugil

AU - Junghans, Christoph

AU - Lookman, Turab

AU - Mohd-Yusof, Jamaludin

AU - Pavel, Robert S.

AU - Rivera, Axel Y.

AU - Roehm, Dominic

AU - McPherson, Allen L.

AU - Germann, Timothy C.

PY - 2014/7

Y1 - 2014/7

N2 - In a common approach to multiscale simulation, an incomplete set of macroscale equations must be supplemented with constitutive data provided by fine-scale simulation. Collecting statistics from these fine-scale simulations is typically the overwhelming computational cost. We reduce this cost by interpolating the results of fine-scale simulation over the spatial domain of the macro-solver. Unlike previous adaptive sampling strategies, we do not interpolate on the potentially very high dimensional space of inputs to the fine-scale simulation. Our approach is local in space and time, avoids the need for a central database, and is designed to parallelize well on large computer clusters. To demonstrate our method, we simulate one-dimensional elastodynamic shock propagation using the Heterogeneous Multiscale Method (HMM); we find that spatial adaptive sampling requires only ≈50×N0.14 fine-scale simulations to reconstruct the stress field at all N grid points. Related multiscale approaches, such as Equation Free methods, may also benefit from spatial adaptive sampling.

AB - In a common approach to multiscale simulation, an incomplete set of macroscale equations must be supplemented with constitutive data provided by fine-scale simulation. Collecting statistics from these fine-scale simulations is typically the overwhelming computational cost. We reduce this cost by interpolating the results of fine-scale simulation over the spatial domain of the macro-solver. Unlike previous adaptive sampling strategies, we do not interpolate on the potentially very high dimensional space of inputs to the fine-scale simulation. Our approach is local in space and time, avoids the need for a central database, and is designed to parallelize well on large computer clusters. To demonstrate our method, we simulate one-dimensional elastodynamic shock propagation using the Heterogeneous Multiscale Method (HMM); we find that spatial adaptive sampling requires only ≈50×N0.14 fine-scale simulations to reconstruct the stress field at all N grid points. Related multiscale approaches, such as Equation Free methods, may also benefit from spatial adaptive sampling.

KW - Adaptive sampling

KW - Multiscale

UR - https://www.scopus.com/pages/publications/84901607780

U2 - 10.1016/j.cpc.2014.03.011

DO - 10.1016/j.cpc.2014.03.011

M3 - 文章

AN - SCOPUS:84901607780

SN - 0010-4655

VL - 185

SP - 1857

EP - 1864

JO - Computer Physics Communications

JF - Computer Physics Communications

IS - 7

ER -

Spatial adaptive sampling in multiscale simulation

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Keywords

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