Spectral Approximation of the Helmholtz Equation with High Wave Numbers

Shen, Jie; Wang, Li-Lian

doi:10.1137/040607332

Cited by 52 publications

(33 citation statements)

References 22 publications

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“…[12,17,18]) in this direction relies on the explicit form of Green's function which is very difficult, if not possible, to extend to more general cases. Our proof is based on an argument in [21,10] (see also [30,9]). More precisely, we take two test functions v = u, (r − a)∂ r u ∈ X in (3.13) successively to obtain a priori estimates without using Green's functions.…”

Section: Jie Shen and Li-lian Wangmentioning

confidence: 99%

“…In particular, it has been shown, at least for some simple cases, that errors of pth order numerical methods for the Helmholtz equation behave like O(k p+1 h p ) (see, for instance, [18,4,30]). Hence, high-order methods are particularly preferable for this type of problem over low-order methods.…”

Section: Introductionmentioning

confidence: 99%

“…The main difficulty here is to obtain error estimates with explicit dependence on the wave number. Among the very few results available in this regard are those in [18,30], where the Helmholtz equation in bounded domains with a first-order approximation to the radiation boundary condition was considered and error estimates with explicit dependence on the wave numbers were derived. To the authors' best knowledge, there seems to be no rigorous error estimate available with explicit dependence on the wave number for a numerical scheme to bounded obstacle scattering.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Analysis of a Spectral-Galerkin Approximation to the Helmholtz Equation in Exterior Domains

Shen¹,

Wang²

2007

SIAM J. Numer. Anal.

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Abstract. An error analysis is presented for the spectral-Galerkin method to the Helmholtz equation in 2-and 3-dimensional exterior domains. The problem in unbounded domains is first reduced to a problem on a bounded domain via the Dirichlet-to-Neumann operator, and then a spectral-Galerkin method is employed to approximate the reduced problem. The error analysis is based on exploring delicate asymptotic behaviors of the Hankel functions and on deriving a priori estimates with explicit dependence on the wave number for both the continuous and the discrete problems. Explicit error bounds with respect to the wave number are derived, and some illustrative numerical examples are also presented.

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Section: Jie Shen and Li-lian Wangmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Analysis of a Spectral-Galerkin Approximation to the Helmholtz Equation in Exterior Domains

Shen¹,

Wang²

2007

SIAM J. Numer. Anal.

Self Cite

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“…[35,36,54]). Then we approximate the coe cient ( ) by a piecewise constant function, i.e., we introduce a function…”

Section: Stability Analysis For Analytical Solutionmentioning

confidence: 99%

“…In recent decades, many scientists presented e cient methods for this class of problems with constant coe cients, including the discrete singular convolution method [2], the hybrid numerical asymptotic method [13], the spectral approximation method [54], the element-free Galerkin method [59,63], the so-called ultra weak variational formulation [34], and the hybrid numerical-asymptotic boundary integral method [8]. In general, these methods need the restriction ℎ = O(1) for the mesh size ℎ in the simulation.…”

Section: Tfpm For Wave Equationmentioning

confidence: 99%

The Tailored Finite Point Method

Han

Huang

2014

Computational Methods in Applied Mathematics

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Abstract:In this paper, a brief review of tailored nite point methods (TFPM) is given. The TFPM is a new approach to construct the numerical solutions of partial di erential equations. The TFPM has been tailored based on the local properties of the solution for each given problem. Especially, the TFPM is very e cient for solutions which are not smooth enough, e.g., for solutions possessing boundary/interior layers or solutions being highly oscillated. Recently, the TFPM has been applied to singular perturbation problems, the Helmholtz equation with high wave numbers, the rst-order wave equation in high frequency cases, transport equations with interface, second-order elliptic equations with rough or highly oscillatory coe cients, etc.

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For Most Frequencies, Strong Trapping Has a Weak Effect in Frequency‐Domain Scattering

Lafontaine

Spence

Wunsch

2020

Comm Pure Appl Math

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It is well‐known that when the geometry and/or coefficients allow stable trapped rays, the outgoing solution operator of the Helmholtz equation grows exponentially through a sequence of real frequencies tending to infinity. In this paper we show that, even in the presence of the strongest possible trapping, if a set of frequencies of arbitrarily small measure is excluded, the Helmholtz solution operator grows at most polynomially as the frequency tends to infinity. One significant application of this result is in the convergence analysis of several numerical methods for solving the Helmholtz equation at high frequency that are based on a polynomial‐growth assumption on the solution operator (e.g. hp‐finite elements, hp‐boundary elements, and certain multiscale methods). The result of this paper shows that this assumption holds, even in the presence of the strongest possible trapping, for most frequencies. © 2021 The Authors. Communications on Pure and Applied Mathematics published by Wiley Periodicals LLC.

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Spectral Approximation of the Helmholtz Equation with High Wave Numbers

Cited by 52 publications

References 22 publications

Analysis of a Spectral-Galerkin Approximation to the Helmholtz Equation in Exterior Domains

Analysis of a Spectral-Galerkin Approximation to the Helmholtz Equation in Exterior Domains

The Tailored Finite Point Method

For Most Frequencies, Strong Trapping Has a Weak Effect in Frequency‐Domain Scattering

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