The Study of the Difference Methods with Variable Grids Seismic Wave Numerical Simulation in Multi-Scale Complex Media

Jie Zhang; Fan Shun Meng; Yang Sen Li

doi:10.4028/www.scientific.net/AMR.1055.254

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1055The Study of the Difference Methods with Variable...

The Study of the Difference Methods with Variable Grids Seismic Wave Numerical Simulation in Multi-Scale Complex Media

Abstract:

In the process of seismic wave field numerical simulation using finite difference method, the simulation accuracy and computational efficiency is one of the keys to the problem which is especially important to the numerical simulation of small scale geological body which velocity changes violently. In order to describe the local structure of medium subtly and guarantee the efficiency of the simulation, this article introduces the variable grid finite difference method to the staggered grid high-order finite difference numerical simulation on the basic of the traditional staggered grid finite difference algorithm to improve the staggered grid spatial algorithm and avoid the reduction of the simulation accuracy and computational efficiency caused by the interpolation factor. The results show that the variable staggered grid numerical simulation of finite difference algorithm can accurately depict the space variation of underground medium physical properties to further enhance the adaptability of numerical simulation of complex medium, it also can provide reliable basis for wave field imaging and the combined interpretation of p-wave and s-wave.

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Periodical:

Advanced Materials Research (Volume 1055)

Pages:

254-258

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1055.254

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Online since:

November 2014

Authors:

Jie Zhang, Fan Shun Meng, Yang Sen Li

Keywords:

Numerical Dispersion, Numerical Simulation, Organic Reef, Perfectly Matched Layer, Staggered Grid, Variable Grids

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References

[1] Y.H. Guo The pool-formed Rule of Natural Gas and Diagenesis of Carboniferous Reservoir in East Sichuan. Journal of Southwestern Petroleum Institute, 3, 16 (1), 1994, pp.1-8.

Google Scholar

[2] Y.J. Feng, C.C. Yang and P. Wu The review of the finite-difference elastic wave motion modeling. Progress in Geophysics, 22(2), 2007, pp.487-491.

Google Scholar

[3] L.G. Dong. Absorptive boundary condition in elastic-wave numerical modeling. Oil Geophysical Prospecting, 34(1), 1999, pp.45-56.

Google Scholar

[4] Q.Z. Du and B. Li. Seismic wave field simulation of VTI medium under combined absorption condition. Oil Geophysical Prospecting, 44(2), 2009, pp.173-178.

Google Scholar

[5] Y.G. Wang, W.J. Xing and W.X. Xie. et al. Study of absorbing boundary condition by perfectly matched layer. Journal of China University of Petroleum(Natural Science), 31(1), 2007, pp.19-24.

Google Scholar

[6] W.J. Li, X.C. Wei and J.R. Ning. A new numeric simulating absorbing boundary condition of elastic wave. Oil Geophysical Prospecting, 44(4), 2009, pp.501-507.

Google Scholar

[7] Q.X. Cai, P.J. He and G. S Qin. et al. Minimum dispersion algorithm by finite-difference numeric modeling and its applications. Oil Geophysical Prospecting, 38 (3), 2003, pp.247-251, 262.

Google Scholar

[8] D.C. Xue and S.G. Wang. Using combined mass matrix to suppress numeric dispersion. Oil Geophysical Prospecting, 43(3), 2008, pp.318-320.

Google Scholar

[9] C.G. Sun, T.J. Gong and Y. L Zhang. et al. Analysis on dispersion and alias in finite- difference solution of wave equation. Oil Geophysical Prospecting, 44(1), 2009, pp.43-48.

Google Scholar

[10] Zhang M., Tang J., Song Q. and Dong Q. (2010) . Backscattering ratio variation and its implications for studying particle composition: a case study in Yellow and East China Seas. J. Geophys. Res. 115(C12014).

DOI: 10.1029/2010jc006098

Google Scholar

[11] Zhang M., Dong Q., Tang J. and Song Q. (2010). Evaluation of the retrieval of total suspended matter concentration in Taihu Lake, China from CBERS-02B CCD. Chinese Journal of Oceanology and Limnology 28(6): 1316-1322.

DOI: 10.1007/s00343-010-9948-7

Google Scholar

[12] Zhang M., Tang J. and Dong Q. (2010). Study on the cross-calibration of charge-coupled device camera on China-Brazil Earth Resources Satellite-02B by moderate resolution imaging spectroradiometer. J. Applied Remote Sensing 4: 043523.

DOI: 10.1117/1.3407597

Google Scholar