Elastic wave equation simulation offers a way to study the wave propagation when creating seismic data. We implement an equivalent dual elastic wave separation equation to simulate the velocity, pressure, divergence, and curl fields in pure P- and S-modes, and apply it in full elastic wave numerical simulation. We give the complete derivations of explicit high-order staggered-grid finite-difference operators, stability condition, dispersion relation, and perfectly matched layer (PML) absorbing boundary condition, and present the resulting discretized formulas for the proposed elastic wave equation. The final numerical results of pure P- and S-modes are completely separated. Storage and computing time requirements are strongly reduced compared to the previous works. Numerical testing is used further to demonstrate the performance of the presented method.

References

1 Chen K. Y., First-order velocity-stress elastic wave field separation scheme for biot two-phase isotropic medium, Chinese Journal of Computational Physics. (2011) 28, no. 3, 404–412, 2-s2.0-79958722686.
Google Scholar
2 Dellinger J. and Etgen J., Wave-field separation in two-dimensional anisotropic media, Geophysics. (1990) 55, no. 7, 914–919, 2-s2.0-0025591585.
Google Scholar
3 Ma D. and Zhu G., Numerical modeling of P-wave and S-wave separation in elastic wavefield, Oil Geophysical Prospecting. (2003) 38, no. 5, 482–486, 2-s2.0-0345448858.
Google Scholar
4 Zhang J.-L., Tian Z.-P., and Wang C.-X., P- and S-wave separated elastic wave equation numerical modeling using 2D staggered-grid, Proceedings of the SEG/San Antonio Annual Meeting, 2007, 2104–2109.
Google Scholar
5 Li Z.-C., Zhang H., Liu Q.-M., and Han W.-G., Numeric simulation of elastic wavefield separation by staggering grid high-order finite-difference algorithm, Oil Geophysical Prospecting. (2007) 42, no. 5, 510–515, 2-s2.0-36248970596.
Google Scholar
6 Dong L.-G., Ma Z.-T., Cao J.-Z., Wang H.-Z., Geng J.-H., Lei B., and Xu S.-Y., A staggered-grid high-order difference method of one-order elastic wave equation, Chinese Journal of Geophysics. (2000) 43, no. 3, 411–419, 2-s2.0-0033924338.
Google Scholar
7 Dong L.-G., Ma Z.-T., and Cao J.-Z., A study on stability of the staggered-grid high-order difference method of first-order elastic wave equation, Chinese Journal of Geophysics. (2000) 43, no. 6, 856–864, 2-s2.0-0034493997.
Google Scholar
8 Berenger J.-P., A perfectly matched layer for the absorption of electromagnetic waves, Journal of Computational Physics. (1994) 114, no. 2, 185–200, 2-s2.0-28044459877, https://doi.org/10.1006/jcph.1994.1159.
Web of Science® Google Scholar
9 Chen K. Y., Study on perfectly matched layer absorbing boundary condition, Geophysical Prospecting for Petroleum. (2010) 49, no. 5, 472–477.
Google Scholar
10 Chen K. Y., Anisotropic analysis of difference approximation in seismic wave numerical modeling, Geophysical Prospecting for Petroleum. (2010) 49, no. 1, 19–22.
Google Scholar
11 Chew W. C. and Liu Q. H., Perfectly matched layers for elastodynamics: a new absorbing boundary condition, Journal of Computational Acoustics. (1996) 4, no. 4, 341–359, https://doi.org/10.1142/S0218396X96000118.
Google Scholar
12 Berenger J.-P., Three-dimensional perfectly matched layer for the absorption of electromagnetic waves, Journal of Computational Physics. (1996) 127, no. 2, 363–379, https://doi.org/10.1006/jcph.1996.0181.
Google Scholar
13 Mitchell A. R., Computational Methods in Partial Differential Equations, 1969, John Wiley & Sons, New York, NY, USA.
Google Scholar
14 Boore D. M., Finite-difference methods for seismic wave propagation in heterogeneous materials, Methods in Computational Physics, 1972, Academic Press, New York, NY, USA, 21–22.
Google Scholar
15 Moczo P., Robertsson J. O. A., and Eisner L., The finite-difference time-domain method for modeling of seismic wave propagation, Advances in Geophysics. (2007) 48, 421–516, 2-s2.0-33751052800, https://doi.org/10.1016/S0065-2687(06)48008-0.
Google Scholar
16 Collino F. and Tsogka C., Application of the perfectly matched absorbing layer model to the linear elastodynamic problem in anisotropic heterogeneous media, Geophysics. (2001) 66, no. 1, 294–307, 2-s2.0-0035071437.
Google Scholar
17 Komatitsch D. and Martin R., An unsplit convolutional perfectly matched layer improved at grazing incidence for the seismic wave equation, Geophysics. (2007) 72, no. 5, SM155–SM167, 2-s2.0-34548525022, https://doi.org/10.1190/1.2757586.
Google Scholar
18 Marcinkovich C. and Olsen K., On the implementation of perfectly matched layers in a three-dimensional fourth-order velocity-stress finite difference scheme, Journal of Geophysical Research B: Solid Earth. (2003) 108, no. 5, 2276–2292, 2-s2.0-0042885467.
Google Scholar

Citing Literature

All articles

Finite-Difference Simulation of Elastic Wave with Separation in Pure P- and S-Modes

Abstract

References

Citing Literature

Figures

References

Information

About Wiley Online Library

Help & Support

Opportunities

Connect with Wiley

Finite-Difference Simulation of Elastic Wave with Separation in Pure P- and S-Modes

Abstract

References

Citing Literature

Figures

References

Related

Information