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Main Authors: Hiptmair, Ralf, Schwab, Christoph, Spence, Euan A.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.01194
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author Hiptmair, Ralf
Schwab, Christoph
Spence, Euan A.
author_facet Hiptmair, Ralf
Schwab, Christoph
Spence, Euan A.
contents We consider frequency-domain acoustic scattering at a homogeneous star-shaped penetrable obstacle, whose shape is uncertain and modelled via a radial spectral parameterization with random coefficients. Using recent results on the stability of Helmholtz transmission problems with piecewise constant coefficients from [A. Moiola and E. A. Spence, Acoustic transmission problems: wavenumber-explicit bounds and resonance-free regions, Mathematical Models and Methods in Applied Sciences, 29 (2019), pp. 317-354] we obtain frequency-explicit statements on the holomorphic dependence of the scattered field and the far-field pattern on the stochastic shape parameters. This paves the way for applying general results on the efficient construction of high-dimensional surrogate models. We also take into account the effect of domain truncation by means of perfectly matched layers (PML). In addition, spatial regularity estimates which are explicit in terms of the wavenumber $k$ permit us to quantify the impact of finite-element Galerkin discretization using high-order Lagrangian finite-element spaces.
format Preprint
id arxiv_https___arxiv_org_abs_2408_01194
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Frequency-Explicit Shape Holomorphy in Uncertainty Quantification for Acoustic Scattering
Hiptmair, Ralf
Schwab, Christoph
Spence, Euan A.
Numerical Analysis
We consider frequency-domain acoustic scattering at a homogeneous star-shaped penetrable obstacle, whose shape is uncertain and modelled via a radial spectral parameterization with random coefficients. Using recent results on the stability of Helmholtz transmission problems with piecewise constant coefficients from [A. Moiola and E. A. Spence, Acoustic transmission problems: wavenumber-explicit bounds and resonance-free regions, Mathematical Models and Methods in Applied Sciences, 29 (2019), pp. 317-354] we obtain frequency-explicit statements on the holomorphic dependence of the scattered field and the far-field pattern on the stochastic shape parameters. This paves the way for applying general results on the efficient construction of high-dimensional surrogate models. We also take into account the effect of domain truncation by means of perfectly matched layers (PML). In addition, spatial regularity estimates which are explicit in terms of the wavenumber $k$ permit us to quantify the impact of finite-element Galerkin discretization using high-order Lagrangian finite-element spaces.
title Frequency-Explicit Shape Holomorphy in Uncertainty Quantification for Acoustic Scattering
topic Numerical Analysis
url https://arxiv.org/abs/2408.01194