An analysis of a discontinuous spectral element method for elastic wave propagation in a heterogeneous material

• Published in: Computational mechanics Vol. 55; no. 4; pp. 789 - 804
• Main Authors: Bin, Jonghoon, Oates, William S., Yousuff Hussaini, M.
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.04.2015; Springer
• Subjects: Accuracy; Analysis; Band structure of solids; Classical and Continuum Physics; Computational Science and Engineering; Dispersions; Elastic waves; Engineering; Galerkin methods; Mathematical models; Methods; Original Paper; Polynomials; Spectra; Theoretical and Applied Mechanics; Wave propagation; Band gap; Floquet–Bloch theory; Dispersion relation; Brillouin zone
• ISSN: 0178-7675; 1432-0924
• DOI: 10.1007/s00466-015-1137-2

The numerical dispersion and dissipation properties of a discontinuous spectral element method are investigated in the context of elastic waves in one dimensional periodic heterogeneous materials. Their frequency dependence and elastic band characteristics are studied. Dispersion relations representing both pass band and stop band structures are derived and used to assess the accuracy of the numerical results. A high-order discontinuous spectral Galerkin method is used to calculate the complex dispersion relations in heterogeneous materials. Floquet–Bloch theory is used to derive the elastic band structure. The accuracy of the dispersion relation is investigated with respect to the spectral polynomial orders for three different cases of materials. Numerical investigations illustrate a spectral convergence in numerical accuracy with respect to the polynomial order based on the elastic band structure and a discontinuous jump of the maximum resolvable frequency within the pass bands resulting in a step-like increase of it with respect to the polynomial order.