Generalized multiscale finite element modeling of acousticwave propagation

Eric Chung; Yalchin Efendiev; Richard L. Gibson; Wing Tat Leung

doi:10.1190/segam2013-1151.1

Generalized multiscale finite element modeling of acousticwave propagation

Eric Chung^*, Yalchin Efendiev, Richard L. Gibson, Wing Tat Leung

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

5 Citations (Scopus)

Abstract

Numerical simulation of elastic and acoustic wave propagation utilizes increasingly large and complex models, providing more realistic and useful results. However, significant challenges remain as direct simulations on fine grid are computationally prohibitive. While in some cases, effective medium theories may be useful, in other situations the distribution of heterogeneities may have more complex effects on waves. We present our results of a new multiscale finite element algorithm for simulating acoustic wave propagation in heterogeneous media. The wave equation is solved on a coarse grid using multiscale basis functions. These multiscale basis functions are chosen as the most dominant modes among the set of all fine grid basis functions, and thus allowing a coarse representation of complex wave structures. Numerical results demonstrate the performance of the method. Long term developments have strong potential to enhance inversion algorithms, since the basis functions need not be regenerated, allowing faster simulations for repeated calculations needed for inversion.

Original language	English
Pages (from-to)	3375-3380
Journal	SEG Technical Program Expanded Abstracts
Volume	32
DOIs	https://doi.org/10.1190/segam2013-1151.1
Publication status	Published - 2013
Externally published	Yes
Event	SEG Houston 2013 Annual Meeting, SEG 2013 - Houston, United States Duration: 22 Sept 2011 → 27 Sept 2011 http://library.seg.org/doi/book/10.1190/segeab.32

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title = "Generalized multiscale finite element modeling of acousticwave propagation",

abstract = "Numerical simulation of elastic and acoustic wave propagation utilizes increasingly large and complex models, providing more realistic and useful results. However, significant challenges remain as direct simulations on fine grid are computationally prohibitive. While in some cases, effective medium theories may be useful, in other situations the distribution of heterogeneities may have more complex effects on waves. We present our results of a new multiscale finite element algorithm for simulating acoustic wave propagation in heterogeneous media. The wave equation is solved on a coarse grid using multiscale basis functions. These multiscale basis functions are chosen as the most dominant modes among the set of all fine grid basis functions, and thus allowing a coarse representation of complex wave structures. Numerical results demonstrate the performance of the method. Long term developments have strong potential to enhance inversion algorithms, since the basis functions need not be regenerated, allowing faster simulations for repeated calculations needed for inversion.",

author = "Eric Chung and Yalchin Efendiev and Gibson, {Richard L.} and Leung, {Wing Tat}",

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T1 - Generalized multiscale finite element modeling of acousticwave propagation

AU - Chung, Eric

AU - Efendiev, Yalchin

AU - Gibson, Richard L.

AU - Leung, Wing Tat

N1 - Publication details (e.g. title, author(s), publication statuses and dates) are captured on an “AS IS” and “AS AVAILABLE” basis at the time of record harvesting from the data source. Suggestions for further amendments or supplementary information can be sent to [email protected].

PY - 2013

Y1 - 2013

N2 - Numerical simulation of elastic and acoustic wave propagation utilizes increasingly large and complex models, providing more realistic and useful results. However, significant challenges remain as direct simulations on fine grid are computationally prohibitive. While in some cases, effective medium theories may be useful, in other situations the distribution of heterogeneities may have more complex effects on waves. We present our results of a new multiscale finite element algorithm for simulating acoustic wave propagation in heterogeneous media. The wave equation is solved on a coarse grid using multiscale basis functions. These multiscale basis functions are chosen as the most dominant modes among the set of all fine grid basis functions, and thus allowing a coarse representation of complex wave structures. Numerical results demonstrate the performance of the method. Long term developments have strong potential to enhance inversion algorithms, since the basis functions need not be regenerated, allowing faster simulations for repeated calculations needed for inversion.

AB - Numerical simulation of elastic and acoustic wave propagation utilizes increasingly large and complex models, providing more realistic and useful results. However, significant challenges remain as direct simulations on fine grid are computationally prohibitive. While in some cases, effective medium theories may be useful, in other situations the distribution of heterogeneities may have more complex effects on waves. We present our results of a new multiscale finite element algorithm for simulating acoustic wave propagation in heterogeneous media. The wave equation is solved on a coarse grid using multiscale basis functions. These multiscale basis functions are chosen as the most dominant modes among the set of all fine grid basis functions, and thus allowing a coarse representation of complex wave structures. Numerical results demonstrate the performance of the method. Long term developments have strong potential to enhance inversion algorithms, since the basis functions need not be regenerated, allowing faster simulations for repeated calculations needed for inversion.

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U2 - 10.1190/segam2013-1151.1

DO - 10.1190/segam2013-1151.1

M3 - RGC 21 - Publication in refereed journal

SN - 1052-3812

VL - 32

SP - 3375

EP - 3380

JO - SEG Technical Program Expanded Abstracts

JF - SEG Technical Program Expanded Abstracts

T2 - SEG Houston 2013 Annual Meeting, SEG 2013

Y2 - 22 September 2011 through 27 September 2011

ER -

Generalized multiscale finite element modeling of acousticwave propagation

Abstract

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