Data-driven superresolution imaging in disordered media

Alexander Christie; Matan Leibovich; Miguel Moscoso; Alexei Novikov; George Papanicolaou; Chrysoula Tsogka

doi:10.1073/pnas.2530449123

Data-driven superresolution imaging in disordered media

Alexander Christie
, Matan Leibovich
, Miguel Moscoso
, Alexei Novikov
, George Papanicolaou
, Chrysoula Tsogka

Research output: Contribution to journal › Article › peer-review

Abstract

We propose a methodology that exploits large and diverse datasets to accurately estimate the ambient medium’s Green’s functions in strongly scattering media. Given these estimates, excellent imaging results are achieved, with a resolution that is better than that of a homogeneous medium. This phenomenon, known as superresolution, arises because the ambient scattering medium effectively enlarges the physical imaging aperture. While superresolution has been demonstrated and analyzed extensively in the context of physical time reversal, time reversal itself is not imaging. Our proposed methodology, based on either conventional optimization methods or neural networks, makes it possible to achieve superresolution imaging in complex media.

Original language	English (US)
Article number	e2530449123
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	123
Issue number	1
DOIs	https://doi.org/10.1073/pnas.2530449123
State	Published - Jan 6 2026

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AU - Christie, Alexander

AU - Leibovich, Matan

AU - Moscoso, Miguel

AU - Novikov, Alexei

AU - Papanicolaou, George

AU - Tsogka, Chrysoula

PY - 2026/1/6

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AB - We propose a methodology that exploits large and diverse datasets to accurately estimate the ambient medium’s Green’s functions in strongly scattering media. Given these estimates, excellent imaging results are achieved, with a resolution that is better than that of a homogeneous medium. This phenomenon, known as superresolution, arises because the ambient scattering medium effectively enlarges the physical imaging aperture. While superresolution has been demonstrated and analyzed extensively in the context of physical time reversal, time reversal itself is not imaging. Our proposed methodology, based on either conventional optimization methods or neural networks, makes it possible to achieve superresolution imaging in complex media.

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Data-driven superresolution imaging in disordered media

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