Fast inverse scattering solutions using the distorted Born iterative method and the multilevel fast multipole algorithm

Hesford, Andrew J.; Chew, Weng Cho

doi:10.1121/1.3458856

Cited by 51 publications

(28 citation statements)

References 40 publications

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“…Previous work in which the FMM is applied in inverse problems are mostly focused on the source reconstruction method, an integral equation technique for antenna diagnostics [24], [25]. The FMM has also been applied to rough surface profile reconstruction [26] and constitutive parameters retrieval when combined with a distorted Born iterative method for acoustic problems [27]. The contribution of this work is not only VSRM speed-up, but also the study of the FMM properties when applied to an inverse electromagnetic problem.…”

Section: Introductionmentioning

confidence: 96%

An Inverse Fast Multipole Method for Geometry Reconstruction Using Scattered Field Information

Álvarez

Martínez-Lorenzo

Las-Heras

et al. 2012

IEEE Trans. Antennas Propagat.

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A novel inverse fast multipole method (FMM) application for accelerating inverse problem solution is presented. The idea is based on the multipole expansion properties of the scattered fields and reconstructed equivalent currents, which allow an easy inversion of the FMM operators, resulting in a forward solution of the inverse problem, i.e., without matrix inversion or cost function minimization. In addition, this technique allows the use of reconstruction domain discretization larger than half a wavelength and overcomes the restriction of having the entire target enclosed by a reconstruction domain, features that also contribute to the reduction of calculation time. Two 3D application examples are presented, highlighting the achieved inverse FMM speed-up with respect to previous inverse scattering methods for geometry reconstruction.Index Terms-Imaging, inverse methods, fast multipole method (FMM), near-field characterization, sources reconstruction method (SRM).

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Section: Introductionmentioning

confidence: 96%

An Inverse Fast Multipole Method for Geometry Reconstruction Using Scattered Field Information

Álvarez

Martínez-Lorenzo

Las-Heras

et al. 2012

IEEE Trans. Antennas Propagat.

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“…13, the multilevel fast multipole algorithm incorporated in the DBIM as developed in Ref. 14, as well as in the time-domain and frequencydomain eigenfunction methods described in Refs. 15 and 16. It is well known that the density profile in many biomedical applications such as breast imaging is not constant.…”

Section: Introductionmentioning

confidence: 99%

Ultrasound tomography for simultaneous reconstruction of acoustic density, attenuation, and compressibility profiles

Mojabi

LoVetri

2015

The Journal of the Acoustical Society of America

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A fast and efficient forward scattering solver is developed for use in ultrasound tomography. The solver is formulated so as to enable the calculation of scattering from large and relatively high-contrast objects with inhomogeneous physical properties that vary simultaneously in acoustic attenuation, compressibility, and density. It is based on the method of moments in conjunction with a novel implementation of the conjugate gradient algorithm which requires the use of the adjoints of the scattering operators. The solver takes advantage of the symmetric block Toeplitz matrix with symmetric Toeplitz blocks property of the Green's function matrix to increase efficiency and only stores the first row of this matrix to reduce memory requirements. This row is then used for the matrix-vector multiplication using the fast Fourier transform technique, thus, resulting in the computational complexity of O(n log n). The marching-on-source technique is also used to provide a good initial guess which allows the conjugate gradient technique to converge faster than initializing with an arbitrary guess. This feature is important in tomographic inversion algorithms which require that the object to be imaged be interrogated via several incident fields. Forward scattering and inversion examples, based on the Conjugate Gradient Least Squares regularized Born Iterative Method, are shown, in two-dimensions, for objects varying in all three physical properties.

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“…For example, estimation and correction of aberration requires simulation of propagation of ultrasound pulses through aberrating media [1–3]. Iterative inverse scattering algorithms such as the distorted Born iterative method [4–7] and the eigenfunction method [8–10] require repeated computation of the forward scattering problem for successive guesses of a reconstructed medium. The arbitrary nature of the scattering media, the desire for automatic satisfaction of the radiation condition, and the embarrassingly parallel nature of solutions at multiple frequencies make frequency-domain integral equation solvers particularly attractive where repeated calculations are required.…”

Section: Introductionmentioning

confidence: 99%

The fast multipole method and Fourier convolution for the solution of acoustic scattering on regular volumetric grids

Hesford

Waag

2010

Journal of Computational Physics

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The fast multipole method (FMM) is applied to the solution of large-scale, three-dimensional acoustic scattering problems involving inhomogeneous objects defined on a regular grid. The grid arrangement is especially well suited to applications in which the scattering geometry is not known a priori and is reconstructed on a regular grid using iterative inverse scattering algorithms or other imaging techniques. The regular structure of unknown scattering elements facilitates a dramatic reduction in the amount of storage and computation required for the FMM, both of which scale linearly with the number of scattering elements. In particular, the use of fast Fourier transforms to compute Green's function convolutions required for neighboring interactions lowers the often-significant cost of finest-level FMM computations and helps mitigate the dependence of FMM cost on finest-level box size. Numerical results demonstrate the efficiency of the composite method as the number of scattering elements in each finest-level box is increased.

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Fast inverse scattering solutions using the distorted Born iterative method and the multilevel fast multipole algorithm

Cited by 51 publications

References 40 publications

An Inverse Fast Multipole Method for Geometry Reconstruction Using Scattered Field Information

An Inverse Fast Multipole Method for Geometry Reconstruction Using Scattered Field Information

Ultrasound tomography for simultaneous reconstruction of acoustic density, attenuation, and compressibility profiles

The fast multipole method and Fourier convolution for the solution of acoustic scattering on regular volumetric grids

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