Wave impedance matrices for cylindrically anisotropic radially inhomogeneous elastic solids

Abstract

Impedance matrices are obtained for radially inhomogeneous structures using the Stroh-like system of six first order differential equations for the time harmonic displacement-traction 6-vector. Particular attention is paid to the newly identified solid-cylinder impedance matrix Z (r) appropriate to cylinders with material at r=0, and its limiting value at that point, the solid-cylinder impedance matrix Z0. We show that Z0 is a fundamental material property depending only on the elastic moduli and the azimuthal order n, that Z (r) is Hermitian and Z0 is negative semi-definite. Explicit solutions for Z0 are presented for monoclinic and higher material symmetry, and the special cases of n=0 and 1 are treated in detail. Two methods are proposed for finding Z (r), one based on the Frobenius series solution and the other using a differential Riccati equation with Z0 as initial value. %in a consistent manner as the solution of an algebraic Riccati equation. The radiation impedance matrix is defined and shown to be non-Hermitian. These impedance matrices enable concise and efficient formulations of dispersion equations for wave guides, and solutions of scattering and related wave problems in cylinders.