Andrew J. Hesford scite author profile

Andrew J. Hesford

5Publications

75Citation Statements Received

67Citation Statements Given

How they've been cited

110

How they cite others

151

Affiliations

University of Rochester, University of Illinois Urbana-Champaign, Urbana University

Publications

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

Hesford

Chew²

2010

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The distorted Born iterative method ͑DBIM͒ computes iterative solutions to nonlinear inverse scattering problems through successive linear approximations. By decomposing the scattered field into a superposition of scattering by an inhomogeneous background and by a material perturbation, large or high-contrast variations in medium properties can be imaged through iterations that are each subject to the distorted Born approximation. However, the need to repeatedly compute forward solutions still imposes a very heavy computational burden. To ameliorate this problem, the multilevel fast multipole algorithm ͑MLFMA͒ has been applied as a forward solver within the DBIM. The MLFMA computes forward solutions in linear time for volumetric scatterers. The typically regular distribution and shape of scattering elements in the inverse scattering problem allow the method to take advantage of data redundancy and reduce the computational demands of the normally expensive MLFMA setup. Additional benefits are gained by employing Kaczmarz-like iterations, where partial measurements are used to accelerate convergence. Numerical results demonstrate both the efficiency of the forward solver and the successful application of the inverse method to imaging problems with dimensions in the neighborhood of ten wavelengths.

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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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A mesh-free approach to acoustic scattering from multiple spheres nested inside a large sphere by using diagonal translation operators

Hesford

Astheimer

Greengard

et al. 2010

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A multiple-scattering approach is presented to compute the solution of the Helmholtz equation when a number of spherical scatterers are nested in the interior of an acoustically large enclosing sphere. The solution is represented in terms of partial-wave expansions, and a linear system of equations is derived to enforce continuity of pressure and normal particle velocity across all material interfaces. This approach yields high-order accuracy and avoids some of the difficulties encountered when using integral equations that apply to surfaces of arbitrary shape. Calculations are accelerated by using diagonal translation operators to compute the interactions between spheres when the operators are numerically stable. Numerical results are presented to demonstrate the accuracy and efficiency of the method.

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On Preconditioning and the Eigensystems of Electromagnetic Radiation Problems

Hesford

Chew²

2008

IEEE Trans. Antennas Propagat.

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A frequency-domain formulation of the Fréchet derivative to exploit the inherent parallelism of the distorted Born iterative method

Hesford

Chew

2006

Waves in Random and Complex Media

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Andrew J. Hesford

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

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

A mesh-free approach to acoustic scattering from multiple spheres nested inside a large sphere by using diagonal translation operators

On Preconditioning and the Eigensystems of Electromagnetic Radiation Problems

A frequency-domain formulation of the Fréchet derivative to exploit the inherent parallelism of the distorted Born iterative method

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