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Guided wave propagation in laterally varying media ‐ I. Theoretical development
Author(s) -
Kennett B. L. N.
Publication year - 1984
Publication title -
geophysical journal of the royal astronomical society
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.302
H-Index - 168
eISSN - 1365-246X
pISSN - 0016-8009
DOI - 10.1111/j.1365-246x.1984.tb02853.x
Subject(s) - superposition principle , eigenfunction , modal , orthogonality , longitudinal wave , wave propagation , reflection (computer programming) , physics , mathematical analysis , position (finance) , classical mechanics , optics , mathematics , geometry , computer science , eigenvalues and eigenvectors , materials science , quantum mechanics , polymer chemistry , programming language , finance , economics
Summary. The propagation of surface waves in a laterally varying medium can be described by representing the wavetrain as a superposition of modal contributions for a reference structure. As the guided waves propagate through a heterogeneous zone the modal coefficients needed to describe the wavetrain vary with position, leading to interconversions between modes and reflection into backward travelling modes. The evolution of the modal terms may be described by a set of first‐order differential equations which allow for coupling to both forward and backward travelling waves; the coefficients in these equations depend on the differences between the actual structure and the reference structure. This system is established using the orthogonality properties of the modal eigenfunctions and is valid for SH ‐waves, P ‐ SV ‐waves and full anisotropy. The reflected and transmitted wavefields for a region of heterogeneity can be related to the incident wave by introducing reflection and transmission matrices which connect the modal coefficients in these fields to those in the incident wavetrain. By considering a sequence of models with increasing width of heterogeneity we are able to derive a set of Ricatti equations for the reflection and transmission matrices which may be solved by initial value techniques. This avoids an awkward two‐point boundary value problem for a large number of coupled equations. The method is demonstrated for 1 Hz Lg ‐ and Sn ‐waves in a multilayered model for which there are 19 coupled modes. The method is applicable to three‐dimensional heterogeneity, and we are able to show that the interconversion between Love and Rayleigh waves, in the presence of gradients in seismic properties transverse to the propagation path, leads to a net rate of increase of the transverse components of the seismogram at the expense of the other components.

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