A Recursive Algorithm for MultiFrequency Acoustic Inverse Source Problems

Bao, Gang; Lü, Shuai; Rundell, William; Xu, Boxi

doi:10.1137/140993648

Cited by 84 publications

(54 citation statements)

References 31 publications

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“…These methods can be classified into two categories: iterative methods and non-iterative methods. While very successful in many cases, iterative methods are usually computationally expensive since they require the solution of a direct problem in every step [2,19]. In contrast, the second group of reconstruction methods, i.e., non-iterative methods, avoids this problem, e.g., [10,11,13,14,17,18].…”

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confidence: 99%

Fast acoustic source imaging using multi-frequency sparse data

Alzaalig

Liu

et al. 2020

Inverse Problems

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We consider the acoustic source imaging problems using multiple frequency data.Using the data of one observation direction/point, we prove that some information (size and location) of the source support can be recovered. A non-iterative method is then proposed to image the source for the Helmholtz equation using multiple frequency far field data of one or several observation directions. The method is simple to implement and extremely fast since it only computes an indicator function on the interested domain using only matrix vector multiplications. Numerical examples are presented to validate the effectiveness of the method.

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confidence: 99%

Fast acoustic source imaging using multi-frequency sparse data

Alzaalig

Liu

et al. 2020

Inverse Problems

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“…The second one is the numerical error of approximated linearized DtN map Λ in (4.4) where the elliptic equation solvers of large wavenumbers and the numerical differentiation of the Neumann boundary data may induce some additional ill-posedness. The error estimate of Algorithm 1 may be carried out by choosing the length and angle sets following the analysis in [4,5]. We intend to report such results in a separate work.…”

Section: Reconstruction Algorithmmentioning

confidence: 99%

Linearized Inverse Schrödinger Potential Problem at a Large Wavenumber

Isakov¹,

Lü²,

Xu³

2020

SIAM J. Appl. Math.

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We investigate recovery of the (Schrödinger) potential function from many boundary measurements at a large wavenumber. By considering such a linearized form, we obtain a Hölder type stability which is a big improvement over a logarithmic stability in low wavenumbers. Furthermore we extend the discussion to the linearized inverse Schrödinger potential problem with attenuation, where an exponential dependence of the attenuation constant is traced in the stability estimate. Based on the linearized problem, a reconstruction algorithm is proposed aiming at the recovery of the Fourier modes of the potential function. By choosing the large wavenumber appropriately, we verify the efficiency of the proposed algorithm by several numerical examples.

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“…Over recent years, intensive attention [6,8,9,16,22,23,24,36,37,38,39] has been focused on the inverse source problem of determining a source F in the Helmholtz equation ∆u + k 2 u = F in Ω, (1.1) from boundary measurements u| Γ and ∂ ν u| Γ , where k > 0 is the wavenumber, Ω ⊂ R N (N = 2, 3) is a bounded Lipschitz domain with boundary Γ and ν denotes the outward unit normal to Γ. A main difficulty of the inverse source problem with a single wavenumber is the non-uniqueness of the source due to the existence of nonradiating sources [3,10,11,15,17], and several numerical methods with multi-frequency measurements [8,9,24,42] have been proposed to overcome it for the source with a arXiv:1801.05584v1 [math.AP] 17 Jan 2018 compact support in the L 2 sense. However, fortunately, with a single wavenumber, the uniqueness can be obtained if a priori information on the source is available [18,23].…”

Section: Introductionmentioning

confidence: 99%

Locating Multiple Multipolar Acoustic Sources Using the Direct Sampling Method

Zhang¹,

Guo²,

Li³

et al. 2019

CiCP

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This work is concerned with the inverse source problem of locating multiple multipolar sources from boundary measurements for the Helmholtz equation. We develop simple and effective sampling schemes for location acquisition of the sources with a single wavenumber. Our algorithms are based on some novel indicator functions whose indicating behaviors could be used to locate multiple multipolar sources. The inversion schemes are totally "direct" in the sense that only simple integral calculations are involved in evaluating the indicator functions. Rigorous mathematical justifications are provided and extensive numerical examples are presented to demonstrate the effectiveness, robustness and efficiency of the proposed methods.

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A Recursive Algorithm for MultiFrequency Acoustic Inverse Source Problems

Cited by 84 publications

References 31 publications

Fast acoustic source imaging using multi-frequency sparse data

Fast acoustic source imaging using multi-frequency sparse data

Linearized Inverse Schrödinger Potential Problem at a Large Wavenumber

Locating Multiple Multipolar Acoustic Sources Using the Direct Sampling Method

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