Isogeometric locally-conformal perfectly matched layer for time-harmonic acoustics

This paper presents an isogeometric formulation of the perfectly matched layer (PML) for time-harmonic acoustic simulations. The new formulation is a generalization of the conventional locally-conformal PML, in which the NURBS patch supporting the PML domain is transformed from real space to complex...

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Bibliographic Details
Published in:Computer methods in applied mechanics and engineering 2021-10, Vol.384, p.113925, Article 113925
Main Authors: Mi, Yongzhen, Yu, Xiang
Format: Article
Language:English
Subjects:
Acoustics
Domains
Fields (mathematics)
Geometric accuracy
Helmholtz equation
Helmholtz equations
Interpolation
Isogeometric analysis
Locally-conformal
Mathematical analysis
Perfectly matched layer
Perfectly matched layers
Robustness (mathematics)
Sound pressure
Sound scatter
Sound sources
Sound transmission
Sound waves
Stretching
Time-harmonic acoustics
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Summary:This paper presents an isogeometric formulation of the perfectly matched layer (PML) for time-harmonic acoustic simulations. The new formulation is a generalization of the conventional locally-conformal PML, in which the NURBS patch supporting the PML domain is transformed from real space to complex space. This is achieved by complex coordinate stretching, based on a stretching vector field indicating the directions in which incident sound waves are absorbed. To solve the difficulty that stretching vectors cannot be defined for control points not lying on the patch, an interpolation method is proposed in which the control-point stretching vectors are calculated by interpolating those at a set of integration points. An automatically matched layer (AML) is also formulated in the isogeometric context. Due to its form-invariant nature, the Helmholtz equation which governs time-harmonic acoustics is kept unchanged in the complex space, except that the Laplacian operator and the sound pressure should be transformed to their complex forms. The performance of the isogeometric PML formulation is discussed through several numerical examples, spanning one to three dimensions and involving both sound radiation and sound scattering problems. It is found that the proposed method presents superior computational accuracy, high geometric adaptivity, and good robustness against challenging geometric features. The geometry-preserving ability inherent in the isogeometric framework brings extra benefits by eliminating geometric errors that are unavoidable in the conventional PML. Meanwhile, these properties are not sensitive to the location of the sound source or the depth of the PML domain. The implementation of the isogeometric PML only requires the replacement of real control-point coordinates by complex ones, making it possible to incorporate the proposed method to various existing numerical routines.
ISSN:0045-7825
1879-2138
DOI:10.1016/j.cma.2021.113925