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Bibliographic Details
Main Authors: Greer, Sarah, Demanet, Laurent
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2304.01013
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author Greer, Sarah
Demanet, Laurent
author_facet Greer, Sarah
Demanet, Laurent
contents Wave-based imaging techniques use wavefield data from receivers on the boundary of a domain to produce an image of the underlying structure in the domain of interest. These images are defined by the imaging condition, which maps recorded data to their reflection points in the domain. In this paper, we introduce a nonlinear modification to the standard imaging condition that can produce images with resolutions greater than that ordinarily expected using the standard imaging condition. We show that the phase of the integrand of the imaging condition, in the Fourier domain, has a special significance in some settings that can be exploited to derive a super-resolved modification of the imaging condition. Whereas standard imaging techniques can resolve features of a length scale of $λ$, our technique allows for resolution level $R < λ$, where the super-resolution factor (SRF) is typically $λ/R$. We show that, in the presence of noise, $R \sim σ$.
format Preprint
id arxiv_https___arxiv_org_abs_2304_01013
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Superresolution with the zero-phase imaging condition
Greer, Sarah
Demanet, Laurent
Classical Physics
Optics
Wave-based imaging techniques use wavefield data from receivers on the boundary of a domain to produce an image of the underlying structure in the domain of interest. These images are defined by the imaging condition, which maps recorded data to their reflection points in the domain. In this paper, we introduce a nonlinear modification to the standard imaging condition that can produce images with resolutions greater than that ordinarily expected using the standard imaging condition. We show that the phase of the integrand of the imaging condition, in the Fourier domain, has a special significance in some settings that can be exploited to derive a super-resolved modification of the imaging condition. Whereas standard imaging techniques can resolve features of a length scale of $λ$, our technique allows for resolution level $R < λ$, where the super-resolution factor (SRF) is typically $λ/R$. We show that, in the presence of noise, $R \sim σ$.
title Superresolution with the zero-phase imaging condition
topic Classical Physics
Optics
url https://arxiv.org/abs/2304.01013