Digital Twin of the Seismogeological Object : Building and Application. / Cheverda, Vladimir; Kolyukhin, Dmitry; Lisitsa, Vadim et al.
Supercomputing - 5th Russian Supercomputing Days, RuSCDays 2019, Revised Selected Papers. ed. / Vladimir Voevodin; Sergey Sobolev. Springer Netherlands, 2019. p. 214-224 (Communications in Computer and Information Science; Vol. 1129 CCIS).Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Research › peer-review
}
TY - GEN
T1 - Digital Twin of the Seismogeological Object
T2 - 5th Russian Supercomputing Days Conference, RuSCDays 2019
AU - Cheverda, Vladimir
AU - Kolyukhin, Dmitry
AU - Lisitsa, Vadim
AU - Protasov, Maksim
AU - Reshetova, Galina
AU - Merzlikina, Anastasiya
AU - Volyanskaya, Victoriay
AU - Petrov, Denis
AU - Shilikov, Valery
AU - Melnik, Artjem
AU - Glinsky, Boris
AU - Chernykh, Igor
AU - Kulikov, Igor
PY - 2019
Y1 - 2019
N2 - The current level of development of numerical methods and high-performance computer systems opens the way to obtain detailed information about the structure of geological objects using 3D seismic study. A universally recognized necessary component that ensures the successful development of modern high-tech technologies for acquiring, processing, and interpreting geophysical data is the complete digital models of geological objects - their digital counterparts. It is on this basis that a detailed assessment of the resolution and information content of the proposed methods and their comparison with the already known processing and interpretation algorithms using the example of a specific geological object becomes possible. Besides, the presence of such digital models allows you to determine the optimal acquisition system, focused on the study of specific features of the object being studied and the selection of the most appropriate graph for processing the data obtained. In this paper, the primary attention is paid to the construction of a realistic three-dimensional geological model with a family of faults, as well as fracture corridors and clusters of cavities. After constructing such an inhomogeneous multi-scale model, we perform a finite-difference numerical simulation of 3D seismic waves’ propagation. The data obtained are processed using the original procedures for extracting scattered/diffracted waves with the subsequent construction of images of the corresponding small-scale objects, which generate these waves. The results obtained are using for verification of the algorithms of scattering and diffraction imaging as well as full waveform inversion.
AB - The current level of development of numerical methods and high-performance computer systems opens the way to obtain detailed information about the structure of geological objects using 3D seismic study. A universally recognized necessary component that ensures the successful development of modern high-tech technologies for acquiring, processing, and interpreting geophysical data is the complete digital models of geological objects - their digital counterparts. It is on this basis that a detailed assessment of the resolution and information content of the proposed methods and their comparison with the already known processing and interpretation algorithms using the example of a specific geological object becomes possible. Besides, the presence of such digital models allows you to determine the optimal acquisition system, focused on the study of specific features of the object being studied and the selection of the most appropriate graph for processing the data obtained. In this paper, the primary attention is paid to the construction of a realistic three-dimensional geological model with a family of faults, as well as fracture corridors and clusters of cavities. After constructing such an inhomogeneous multi-scale model, we perform a finite-difference numerical simulation of 3D seismic waves’ propagation. The data obtained are processed using the original procedures for extracting scattered/diffracted waves with the subsequent construction of images of the corresponding small-scale objects, which generate these waves. The results obtained are using for verification of the algorithms of scattering and diffraction imaging as well as full waveform inversion.
KW - Digital twin
KW - Discrete elements
KW - Fault formation
KW - Full waveform inversion
KW - GPU parallelization
KW - MPI+OpenMP parallelization
KW - Multiscale geological media
KW - Scattering imaging
UR - http://www.scopus.com/inward/record.url?scp=85076842717&partnerID=8YFLogxK
U2 - 10.1007/978-3-030-36592-9_18
DO - 10.1007/978-3-030-36592-9_18
M3 - Conference contribution
AN - SCOPUS:85076842717
SN - 9783030365912
T3 - Communications in Computer and Information Science
SP - 214
EP - 224
BT - Supercomputing - 5th Russian Supercomputing Days, RuSCDays 2019, Revised Selected Papers
A2 - Voevodin, Vladimir
A2 - Sobolev, Sergey
PB - Springer Netherlands
Y2 - 23 September 2019 through 24 September 2019
ER -
ID: 25773145