A review of finite-element methods for time-harmonic acoustics

Thompson, Lonny L.

doi:10.1121/1.2164987

Cited by 289 publications

(195 citation statements)

References 192 publications

(189 reference statements)

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“…There is a large body of existing work on solving the wave equation developed over the past few decades. These methods may be roughly classified into finite element method (FEM) [10], boundary element method (BEM) [11], finite-difference time-domain (FDTD) [5] and spectral methods [12].…”

Section: Numerical Solvers For the Wave Equationmentioning

confidence: 99%

An efficient GPU-based time domain solver for the acoustic wave equation

Mehra¹,

Raghuvanshi²,

Savioja³

et al. 2012

Applied Acoustics

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An efficient algorithm for time-domain solution of the acoustic wave equation for the purpose of room acoustics is presented. It is based on adaptive rectangular decomposition of the scene and uses analytical solutions within the partitions that rely on spatially invariant speed of sound. This technique is suitable for auralizations and sound field visualizations, even on coarse meshes approaching the Nyquist limit. It is demonstrated that by carefully mapping all components of the algorithm to match the parallel processing capabilities of graphics processors (GPUs), significant improvement in performance is gained compared to the corresponding CPU-based solver, while maintaining the numerical accuracy. Substantial performance gain over a high-order finite-difference time-domain method is observed. Using this technique, a 1 second long simulation can be performed on scenes of air volume 7500 m 3 till 1650 Hz within 18 minutes compared to the corresponding CPU-based solver that takes around 5 hours and a high-order finite-difference time-domain solver that could take up to three weeks on a desktop computer. To the best of the authors' knowledge, this is the fastest time-domain solver for modeling the room acoustics of large, complex-shaped 3D scenes that generates accurate results for both auralization and visualization.

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Section: Numerical Solvers For the Wave Equationmentioning

confidence: 99%

An efficient GPU-based time domain solver for the acoustic wave equation

Mehra¹,

Raghuvanshi²,

Savioja³

et al. 2012

Applied Acoustics

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“…It has successfully been used for interior scattering problems like acoustic scattering in a car cabin [1] as well as for exterior problems. A review [2] gives an overview of recent research on finite element methods for acoustic problems. Since the paper [3] the research on the construction of absorbing boundary conditions and absorbing layers at the truncation boundary of the exterior domain has been active; see [2] and references therein.…”

Section: Introductionmentioning

confidence: 99%

“…A review [2] gives an overview of recent research on finite element methods for acoustic problems. Since the paper [3] the research on the construction of absorbing boundary conditions and absorbing layers at the truncation boundary of the exterior domain has been active; see [2] and references therein. The size of the scattering problems is often limited in high frequency problems because the methods become ineffective as the frequency grows.…”

Section: Introductionmentioning

confidence: 99%

A damping preconditioner for time-harmonic wave equations in fluid and elastic material

Airaksinen

Pennanen

Toivanen

2009

Journal of Computational Physics

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“…Also, a time discretization error must be considered in a time-domain analysis. These requirements engender the solution of large-scale problems with many degrees of freedom (DOF) and many time steps for a simulation at high frequencies.Many dispersion reduction methods have been developed to increase the computational efficiency [1][2][3][4][5][6]. The authors have also proposed some dispersion-reduced TD-FEM based on an implicit method to solve the large-scale problems efficiently [1,2].…”

mentioning

confidence: 99%

Applicability of an explicit time-domain finite-element method on room acoustics simulation

Okuzono

Otsuru

Sakagami

2015

Acoust. Sci. & Tech.

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IntroductionRecently the time-domain finite-element method (TD-FEM) is becoming an efficient wave-based numerical method for wideband room acoustics simulation up to several kilohertz frequencies, with the drastic advancement of computer technology [1,2]. However, a cost-efficient simulation up to high frequencies using the method is still considered to be a difficult task, due to the high computational cost. A dispersion error, which is an inherent discretization error coming from spatial and time discretizations of a computational domain, is one of the reasons for the high computational cost. Because of the error, a spatial discretization requirement known as a rule of thumb is imposed in a mesh generation process to yield reliable results. Also, a time discretization error must be considered in a time-domain analysis. These requirements engender the solution of large-scale problems with many degrees of freedom (DOF) and many time steps for a simulation at high frequencies.Many dispersion reduction methods have been developed to increase the computational efficiency [1][2][3][4][5][6]. The authors have also proposed some dispersion-reduced TD-FEM based on an implicit method to solve the large-scale problems efficiently [1,2]. Also, there exists an explicit TD-FEM with a simple dispersion reduction technique called modified integration rules (MIR) [5], in which fourth-order accuracy with respect to the dispersion error can be obtained for the idealized case using square or cubic finite elements (FEs). This explicit method is very attractive for realizing an efficient room acoustics simulation because it does not need a solution of a linear system of equations at each time step. However, as presented in the literature [5], the explicit method does not consider a dissipation term for treating an absorption at boundaries, which is important for room acoustics simulation.When a sound field inside a room with an finite impedance boundary is analyzed using this explicit method, a time derivative of sound pressure related to the dissipation term has to be approximated by a less-accurate backward difference even though time derivatives of other physical quantities are approximated by a second-order accurate

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A review of finite-element methods for time-harmonic acoustics

Cited by 289 publications

References 192 publications

An efficient GPU-based time domain solver for the acoustic wave equation

An efficient GPU-based time domain solver for the acoustic wave equation

A damping preconditioner for time-harmonic wave equations in fluid and elastic material

Applicability of an explicit time-domain finite-element method on room acoustics simulation

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