Wave propagation in an inhomogeneous cross-anisotropic medium

Analytical solutions for wave velocities and wave vectors are yielded for a continuously inhomogeneous cross-anisotropic medium, in which Young's moduli (E, E') and shear modulus (G') varied exponentially as depth increased. However, for the rest moduli in cross-anisotropic materials, v and v' remained constant regardless of depth. We assume that cross-anisotropy planes are parallel to the horizontal surface. The generalized Hooke's law, strain displacement relationships, and equilibrium equations are integrated to constitute governing equations. In these equations, displacement components are fundamental variables and, hence, the solutions of three quasi-wave velocities, V-P, V-SV, and V-SH, and the wave vectors, (l) over right arrowP (l) over right arrow (SV) and (l) over right arrow (SH), can be generated for the inhomogeneous cross-anisotropic media. The proposed solutions and those obtained by Daley and Hron, and Levin correlate well with each other when the inhomogeneity parameter, k, is 0. Additionally, parametric study results indicate that the magnitudes and directions of wave velocity are markedly affected by (1) the inhomogeneous parameter, k; (2) the type and degree of geomaterial anisotropy (E/E', G'/E', and v/v'); and (3) the phase angle, theta. Consequently, one must consider the influence of inhomogeneous characteristic when investigating the behaviors of wave propagation in a cross-anisotropic medium. Copyright (C) 2009 John Wiley & Sons, Ltd.