Szczegóły publikacji
Opis bibliograficzny
A nonlocal finite difference scheme for simulation of wave propagation in 2D models with reduced numerical dispersion / A. MARTOWICZ, M. Ruzzene, W. J. STASZEWSKI, J. J. Rimoli, T. UHL // W: Health monitoring of structural and biological systems 2014 : 10–13 March 2014, San Diego, California, USA / ed. Tribikram Kundu. — Bellingham : SPIE, cop. 2014. — (Proceedings of SPIE / The International Society for Optical Engineering ; ISSN 0277-786X ; vol. 9064). — ISBN: 9780819499905. — S. 90640F-1–90640F-8. — Bibliogr. s. 90640F-8, Abstr.
Autorzy (5)
- AGHMartowicz Adam
- Ruzzene Massimo
- AGHStaszewski Wiesław Jerzy
- Rimoli Julian J.
- AGHUhl Tadeusz
Słowa kluczowe
Dane bibliometryczne
| ID BaDAP | 85305 |
|---|---|
| Data dodania do BaDAP | 2014-11-06 |
| DOI | 10.1117/12.2045252 |
| Rok publikacji | 2014 |
| Typ publikacji | materiały konferencyjne (aut.) |
| Otwarty dostęp |  |
| Konferencja | Conference on Health Monitoring of Structural and Biological Systems |
| Czasopismo/seria | Proceedings of SPIE / The International Society for Optical Engineering |
Abstract
The work deals with the reduction of numerical dispersion in simulations of wave propagation in solids. The phenomenon of numerical dispersion naturally results from time and spatial discretization present in a numerical model of mechanical continuum. Although discretization itself makes possible to model wave propagation in structures with complicated geometries and made of different materials, it inevitably causes simulation errors when improper time and length scales are chosen for the simulations domains. Therefore, by definition, any characteristic parameter for spatial and time resolution must create limitations on maximal wavenumber and frequency for a numerical model. It should be however noted that expected increase of the model quality and its functionality in terms of affordable wavenumbers, frequencies and speeds should not be achieved merely by denser mesh and reduced time integration step. The computational cost would be simply unacceptable. The authors present a nonlocal finite difference scheme with the coefficients calculated applying a Fourier series, which allows for considerable reduction of numerical dispersion. There are presented the results of analyses for 2D models, with isotropic and anisotropic materials, fulfilling the planar stress state. Reduced numerical dispersion is shown in the dispersion surfaces for longitudinal and shear waves propagating for different directions with respect to the mesh orientation and without dramatic increase of required number of nonlocal interactions. A case with the propagation of longitudinal wave in composite material is studied with given referential solution of the initial value problem for verification of the time-domain outcomes. The work gives a perspective of modeling of any type of real material dispersion according to measurements and with assumed accuracy.
