A multiscale method for porous microstructures
A multiscale method for porous microstructures
View/Date of Publication
11.2014Publisher
Institut für Numerische Simulation (INS)Publisher Location
BonnMetadata
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Citable Link (Handle URI) 
https://hdl.handle.net/20.500.11811/11915
Abstract
In this paper we develop a multiscale method to solve problems in complicated porous microstructures with Neumann boundary conditions. By using a coarse-grid quasi-interpolation operator to define a fine detail space and local orthogonal decomposition, we construct multiscale corrections to coarse-grid basis functions with microstructure. By truncating the corrector functions we are able to make a computationally efficient scheme. Error results and analysis are presented. A key component of this analysis is the investigation of the Poincaré and inverse inequality constants in perforated domains as they may contain micro-structural information. Using first a theoretical method based on extensions of functions and then constructive method originally developed for weighted Poincaré inequalities, we are able to obtain estimates on Poincaré constants with respect to scale and separation length of the pores. Finally, two numerical examples are presented to verify our estimates.
Subjects
localization, multiscale methods, Poincaré constants
Classification (DDC)
510 Mathematik 518 Numerische AnalysisFirst Publication
https://ins.uni-bonn.de/publication/preprintsRelated Publications
https://doi.org/10.1137/140995210Part of Series
INS Preprints ; 1410Brown, Donald L.; Peterseim, Daniel: A multiscale method for porous microstructures. In: INS Preprints, 1410.
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/11915
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/11915
@unpublished{handle:20.500.11811/11915,
author = {{Donald L. Brown} and {Daniel Peterseim}},
title = {A multiscale method for porous microstructures},
publisher = {Institut für Numerische Simulation (INS)},
year = 2014,
month = nov,
INS Preprints},
volume = 1410,
note = {In this paper we develop a multiscale method to solve problems in complicated porous microstructures with Neumann boundary conditions. By using a coarse-grid quasi-interpolation operator to define a fine detail space and local orthogonal decomposition, we construct multiscale corrections to coarse-grid basis functions with microstructure. By truncating the corrector functions we are able to make a computationally efficient scheme. Error results and analysis are presented. A key component of this analysis is the investigation of the Poincaré and inverse inequality constants in perforated domains as they may contain micro-structural information. Using first a theoretical method based on extensions of functions and then constructive method originally developed for weighted Poincaré inequalities, we are able to obtain estimates on Poincaré constants with respect to scale and separation length of the pores. Finally, two numerical examples are presented to verify our estimates.},
url = {https://hdl.handle.net/20.500.11811/11915}
}
author = {{Donald L. Brown} and {Daniel Peterseim}},
title = {A multiscale method for porous microstructures},
publisher = {Institut für Numerische Simulation (INS)},
year = 2014,
month = nov,
INS Preprints},
volume = 1410,
note = {In this paper we develop a multiscale method to solve problems in complicated porous microstructures with Neumann boundary conditions. By using a coarse-grid quasi-interpolation operator to define a fine detail space and local orthogonal decomposition, we construct multiscale corrections to coarse-grid basis functions with microstructure. By truncating the corrector functions we are able to make a computationally efficient scheme. Error results and analysis are presented. A key component of this analysis is the investigation of the Poincaré and inverse inequality constants in perforated domains as they may contain micro-structural information. Using first a theoretical method based on extensions of functions and then constructive method originally developed for weighted Poincaré inequalities, we are able to obtain estimates on Poincaré constants with respect to scale and separation length of the pores. Finally, two numerical examples are presented to verify our estimates.},
url = {https://hdl.handle.net/20.500.11811/11915}
}
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