Conventional explicit finite-difference methods for solving the elastic-wave equation suffer from numerical dispersion when too few samples per wavelength are used. A nearly analytic discrete method for suppressing the numerical dispersion was proposed recently by Yang et al. (2003a). In this paper, we present a modified algorithm of the nearly-analytic discrete method (NADM) for modelling seismic propagation in 2D anisotropic media. We also investigate the numerical dispersion of the modified algorithm using numerical examples and compare numerically the dispersion errors and the wavefield results computed using the modified algorithm against those of our previous method and other finite-difference (FD) methods. We show that, compared with the improved NADM, the modified algorithm for the 2D case can further minimize the numerical dispersion, while its computational cost and storage space are the same as those of our previous method. Wavefield snapshot for two-layer heterogeneous medium and three-component synthetic VSP seismograms in three-layer transversely isotropic media with a vertical symmetry axis, generated using the modified algorithm, are also reported. Numerical results demonstrate that the modified algorithm further reduces the numerical dispersion and source noise caused by the discretization of elastic-wave equations when too few samples per wavelength are used or when models have large velocity contrast and strong anisotropy.

• 出版日期2010-1
• 单位清华大学; 西南石油大学