Time splitting for wave equations in random media

Guillaume Bal; Lenya Ryzhik

Displaying similar documents to “Time splitting for wave equations in random media”

Time splitting for wave equations in random media

Guillaume Bal, Lenya Ryzhik (2010)

ESAIM: Mathematical Modelling and Numerical Analysis

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Numerical simulation of high frequency waves in highly heterogeneous media is a challenging problem. Resolving the fine structure of the wave field typically requires extremely small time steps and spatial meshes. We show that capturing macroscopic quantities of the wave field, such as the wave energy density, is achievable with much coarser discretizations. We obtain such a result using a time splitting algorithm that solves separately and successively propagation and scattering...

On elastic waves in a medium with randomly distributed cylinders.

Bose, S.K., Debnath, L. (1981)

International Journal of Mathematics and Mathematical Sciences

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An optimal dimension of submerged parallel bars as a wave reflector.

Pudjaprasetya, S.R., Chendra, H.D. (2009)

Bulletin of the Malaysian Mathematical Sciences Society. Second Series

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Multiscale analysis of wave propagation in random media. Application to correlation-based imaging

Josselin Garnier (2013-2014)

Séminaire Laurent Schwartz — EDP et applications

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We consider sensor array imaging with the purpose to image reflectors embedded in a medium. Array imaging consists in two steps. In the first step waves emitted by an array of sources probe the medium to be imaged and are recorded by an array of receivers. In the second step the recorded signals are processed to form an image of the medium. Array imaging in a scattering medium is limited because coherent signals recorded at the receiver array and coming from a reflector to be imaged...

Solitary waves, solitons and related (nonlinear) waves in dissipative media.

Manuel G. Velarde (1993)

Revista de la Real Academia de Ciencias Exactas Físicas y Naturales

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Numerical solution of Boussinesq equations as a model of interfacial-wave propagation.

Wiryanto, L.H. (2005)

Bulletin of the Malaysian Mathematical Sciences Society. Second Series

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Rayleigh wave scattering at the foot of a mountain.

Deshwal, P.S., Mann, K.K. (1987)

International Journal of Mathematics and Mathematical Sciences

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Wave growth patterns in a nonlinear dispersive system with instability and dissipation.

Gera, Dinesh, Gautam, Mridul, Gangarao, Hota V.S. (1997)

International Journal of Mathematics and Mathematical Sciences

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Multi-scaled diffusion-approximation. Applications to wave propagation in random media.

Josselin Garnier (2010)

ESAIM: Probability and Statistics

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In this paper a multi-scaled diffusion-approximation theorem is proved so as to unify various applications in wave propagation in random media: transmission of optical modes through random planar waveguides; time delay in scattering for the linear wave equation; decay of the transmission coefficient for large lengths with fixed output and phase difference in weakly nonlinear random media.