Standard

Modeling and imaging of multiscale geological media : Exploding reflection revisited. / Landa, Evgeny; Reshetova, Galina; Tcheverda, Vladimir.

в: Geosciences (Switzerland), Том 8, № 12, 476, 12.2018.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

APA

Vancouver

Landa E, Reshetova G, Tcheverda V. Modeling and imaging of multiscale geological media: Exploding reflection revisited. Geosciences (Switzerland). 2018 дек.;8(12):476. doi: 10.3390/geosciences8120476

Author

Landa, Evgeny ; Reshetova, Galina ; Tcheverda, Vladimir. / Modeling and imaging of multiscale geological media : Exploding reflection revisited. в: Geosciences (Switzerland). 2018 ; Том 8, № 12.

BibTeX

@article{9d2bee9370534d25a29e234a3c7fc564,
title = "Modeling and imaging of multiscale geological media: Exploding reflection revisited",
abstract = "Computation of Common Middle Point seismic sections and their subsequent time migration and diffraction imaging provides very important knowledge about the internal structure of 3D heterogeneous geological media and are key elements for successive geological interpretation. Full-scale numerical simulation, that computes all single shot seismograms, provides a full understanding of how the features of the image reflect the properties of the subsurface prototype. Unfortunately, this kind of simulations of 3D seismic surveys for realistic geological media needs huge computer resources, especially for simulation of seismic waves{\textquoteright} propagation through multiscale media like cavernous fractured reservoirs. Really, we need to combine smooth overburden with microstructure of reservoirs, which forces us to use locally refined grids. However, to resolve realistic statements with huge multi-shot/multi-offset acquisitions it is still not enough to provide reasonable needs of computing resources. Therefore, we propose to model 3D Common Middle Point seismic cubes directly, rather than shot-by-shot simulation with subsequent stacking. To do that we modify the well-known “exploding reflectors principle” for 3D heterogeneous multiscale media by use of the finite-difference technique on the base of grids locally refined in time and space. We develop scalable parallel software, which needs reasonable computational costs to simulate realistic models and acquisition. Numerical results for simulation of Common Middle Points sections and their time migration are presented and discussed.",
keywords = "Common middle point, Diffraction/scattering imaging, Finite-difference simulation, Local grid refinement in time and space, Propagator, Small-scale heterogeneities, Spatial reflector, diffraction/scattering imaging, propagator, local grid refinement in time and space, spatial reflector, common middle point, small-scale heterogeneities, finite-difference simulation",
author = "Evgeny Landa and Galina Reshetova and Vladimir Tcheverda",
year = "2018",
month = dec,
doi = "10.3390/geosciences8120476",
language = "English",
volume = "8",
journal = "Geosciences (Switzerland)",
issn = "2076-3263",
publisher = "MDPI AG",
number = "12",

}

RIS

TY - JOUR

T1 - Modeling and imaging of multiscale geological media

T2 - Exploding reflection revisited

AU - Landa, Evgeny

AU - Reshetova, Galina

AU - Tcheverda, Vladimir

PY - 2018/12

Y1 - 2018/12

N2 - Computation of Common Middle Point seismic sections and their subsequent time migration and diffraction imaging provides very important knowledge about the internal structure of 3D heterogeneous geological media and are key elements for successive geological interpretation. Full-scale numerical simulation, that computes all single shot seismograms, provides a full understanding of how the features of the image reflect the properties of the subsurface prototype. Unfortunately, this kind of simulations of 3D seismic surveys for realistic geological media needs huge computer resources, especially for simulation of seismic waves’ propagation through multiscale media like cavernous fractured reservoirs. Really, we need to combine smooth overburden with microstructure of reservoirs, which forces us to use locally refined grids. However, to resolve realistic statements with huge multi-shot/multi-offset acquisitions it is still not enough to provide reasonable needs of computing resources. Therefore, we propose to model 3D Common Middle Point seismic cubes directly, rather than shot-by-shot simulation with subsequent stacking. To do that we modify the well-known “exploding reflectors principle” for 3D heterogeneous multiscale media by use of the finite-difference technique on the base of grids locally refined in time and space. We develop scalable parallel software, which needs reasonable computational costs to simulate realistic models and acquisition. Numerical results for simulation of Common Middle Points sections and their time migration are presented and discussed.

AB - Computation of Common Middle Point seismic sections and their subsequent time migration and diffraction imaging provides very important knowledge about the internal structure of 3D heterogeneous geological media and are key elements for successive geological interpretation. Full-scale numerical simulation, that computes all single shot seismograms, provides a full understanding of how the features of the image reflect the properties of the subsurface prototype. Unfortunately, this kind of simulations of 3D seismic surveys for realistic geological media needs huge computer resources, especially for simulation of seismic waves’ propagation through multiscale media like cavernous fractured reservoirs. Really, we need to combine smooth overburden with microstructure of reservoirs, which forces us to use locally refined grids. However, to resolve realistic statements with huge multi-shot/multi-offset acquisitions it is still not enough to provide reasonable needs of computing resources. Therefore, we propose to model 3D Common Middle Point seismic cubes directly, rather than shot-by-shot simulation with subsequent stacking. To do that we modify the well-known “exploding reflectors principle” for 3D heterogeneous multiscale media by use of the finite-difference technique on the base of grids locally refined in time and space. We develop scalable parallel software, which needs reasonable computational costs to simulate realistic models and acquisition. Numerical results for simulation of Common Middle Points sections and their time migration are presented and discussed.

KW - Common middle point

KW - Diffraction/scattering imaging

KW - Finite-difference simulation

KW - Local grid refinement in time and space

KW - Propagator

KW - Small-scale heterogeneities

KW - Spatial reflector

KW - diffraction/scattering imaging

KW - propagator

KW - local grid refinement in time and space

KW - spatial reflector

KW - common middle point

KW - small-scale heterogeneities

KW - finite-difference simulation

UR - http://www.scopus.com/inward/record.url?scp=85062647098&partnerID=8YFLogxK

U2 - 10.3390/geosciences8120476

DO - 10.3390/geosciences8120476

M3 - Article

AN - SCOPUS:85062647098

VL - 8

JO - Geosciences (Switzerland)

JF - Geosciences (Switzerland)

SN - 2076-3263

IS - 12

M1 - 476

ER -

ID: 25773730