A data-driven approach to solving a 1D inverse scattering problem
Publication date
2023-06-01
Authors
van Leeuwen, Tristan
Tataris, Andreas
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Document Type
Article
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Abstract
In this paper, we extend a recently proposed approach for inverse scattering with Neumann boundary conditions [Druskin et al., Inverse Probl. 37, 075003 (2021)] to the 1D Schrödinger equation with impedance (Robin) boundary conditions. This method approaches inverse scattering in two steps: first, to extract a reduced order model (ROM) directly from the data and, subsequently, to extract the scattering potential from the ROM. We also propose a novel data-assimilation (DA) inversion method based on the ROM approach, thereby avoiding the need for a Lanczos-orthogonalization (LO) step. Furthermore, we present a detailed numerical study and A comparison of the accuracy and stability of the DA and LO methods.
Keywords
Geophysical techniques, Noisy data, Integral equations, Numerical linear algebra, Partial differential equations, Inverse scattering, Born approximation, Scattering problem, Schrodinger equations, General Physics and Astronomy
Citation
van Leeuwen, T & Tataris, A 2023, 'A data-driven approach to solving a 1D inverse scattering problem', AIP Advances, vol. 13, no. 6, 065310. https://doi.org/10.1063/5.0154182