Modeling Across Scales: Discrete Geometric Structures in Homogenization and Inverse Homogenization

Mathieu Desbrun; Roger D. Donaldson; Houman Owhadi

doi:10.1002/9783527671632.ch02

Modeling Across Scales: Discrete Geometric Structures in Homogenization and Inverse Homogenization

Mathieu Desbrun
, Roger D. Donaldson
, Houman Owhadi

California Institute of Technology Division of Engineering and Applied Science

Résultats de recherche: Le chapitre dans un livre, un rapport, une anthologie ou une collection › Chapitre › Revue par des pairs

Résumé

Imaging and simulation methods are typically constrained to resolutions much coarser than the scale of physical microstructures present in body tissues or geological features. Mathematical homogenization and numerical homogenization address this practical issue by identifying and computing appropriate spatial averages that result in accuracy and consistency between the macroscales we observe and the underlying microscale models we assume. Among the various applications benefiting from homogenization, electrical impedance tomography (EIT) images the electrical conductivity of a body by measuring electrical potentials consequential to electric currents applied to the exterior of the body. EIT is routinely used in breast cancer detection and cardiopulmonary imaging, where current flow in fine-scale tissues underlies the resulting coarse-scale images.

langue originale	Anglais
titre	Multiscale Analysis and Nonlinear Dynamics
Sous-titre	From Genes to the Brain
Editeur	Wiley-VCH Verlag
Pages	19-64
Nombre de pages	46
ISBN (Electronique)	9783527671632
ISBN (imprimé)	9783527411986
Les DOIs	https://doi.org/10.1002/9783527671632.ch02
état	Publié - 31 juil. 2013
Modification externe	Oui

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title = "Modeling Across Scales: Discrete Geometric Structures in Homogenization and Inverse Homogenization",

abstract = "Imaging and simulation methods are typically constrained to resolutions much coarser than the scale of physical microstructures present in body tissues or geological features. Mathematical homogenization and numerical homogenization address this practical issue by identifying and computing appropriate spatial averages that result in accuracy and consistency between the macroscales we observe and the underlying microscale models we assume. Among the various applications benefiting from homogenization, electrical impedance tomography (EIT) images the electrical conductivity of a body by measuring electrical potentials consequential to electric currents applied to the exterior of the body. EIT is routinely used in breast cancer detection and cardiopulmonary imaging, where current flow in fine-scale tissues underlies the resulting coarse-scale images.",

keywords = "Calderon's problem, Electrical impedance, Harmonic coordinates, Homogenization, Incomplete measurements, Inverse homogenization",

author = "Mathieu Desbrun and Donaldson, \{Roger D.\} and Houman Owhadi",

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Modeling Across Scales: Discrete Geometric Structures in Homogenization and Inverse Homogenization. / Desbrun, Mathieu; Donaldson, Roger D.; Owhadi, Houman.
Multiscale Analysis and Nonlinear Dynamics: From Genes to the Brain. Wiley-VCH Verlag, 2013. p. 19-64.

Résultats de recherche: Le chapitre dans un livre, un rapport, une anthologie ou une collection › Chapitre › Revue par des pairs

TY - CHAP

T1 - Modeling Across Scales

T2 - Discrete Geometric Structures in Homogenization and Inverse Homogenization

AU - Desbrun, Mathieu

AU - Donaldson, Roger D.

AU - Owhadi, Houman

PY - 2013/7/31

Y1 - 2013/7/31

N2 - Imaging and simulation methods are typically constrained to resolutions much coarser than the scale of physical microstructures present in body tissues or geological features. Mathematical homogenization and numerical homogenization address this practical issue by identifying and computing appropriate spatial averages that result in accuracy and consistency between the macroscales we observe and the underlying microscale models we assume. Among the various applications benefiting from homogenization, electrical impedance tomography (EIT) images the electrical conductivity of a body by measuring electrical potentials consequential to electric currents applied to the exterior of the body. EIT is routinely used in breast cancer detection and cardiopulmonary imaging, where current flow in fine-scale tissues underlies the resulting coarse-scale images.

AB - Imaging and simulation methods are typically constrained to resolutions much coarser than the scale of physical microstructures present in body tissues or geological features. Mathematical homogenization and numerical homogenization address this practical issue by identifying and computing appropriate spatial averages that result in accuracy and consistency between the macroscales we observe and the underlying microscale models we assume. Among the various applications benefiting from homogenization, electrical impedance tomography (EIT) images the electrical conductivity of a body by measuring electrical potentials consequential to electric currents applied to the exterior of the body. EIT is routinely used in breast cancer detection and cardiopulmonary imaging, where current flow in fine-scale tissues underlies the resulting coarse-scale images.

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KW - Harmonic coordinates

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KW - Incomplete measurements

KW - Inverse homogenization

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PB - Wiley-VCH Verlag

ER -

Modeling Across Scales: Discrete Geometric Structures in Homogenization and Inverse Homogenization

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