Spectral Analysis of Discretized Boundary Integral Operators in 3D: a High-Frequency Perspective
By: V. Giunzioni, A. Merlini, F. P. Andriulli
Potential Business Impact:
Makes computer simulations of waves more accurate.
When modeling propagation and scattering phenomena using integral equations discretized by the boundary element method, it is common practice to approximate the boundary of the scatterer with a mesh comprising elements of size approximately equal to a fraction of the wavelength $\lambda$ of the incident wave, e.g., $\lambda/10$. In this work, by analyzing the spectra of the operator matrices, we show a discrepancy with respect to the continuous operators which grows with the simulation frequency, challenging the common belief that the aforementioned widely used discretization approach is sufficient to maintain the accuracy of the solution constant when increasing the frequency.
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