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Autori principali: Valantinas, Laurynas, Vettenburg, Tom
Natura: Preprint
Pubblicazione: 2022
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Accesso online:https://arxiv.org/abs/2208.01118
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author Valantinas, Laurynas
Vettenburg, Tom
author_facet Valantinas, Laurynas
Vettenburg, Tom
contents Heterogeneous materials such as biological tissue scatter light in random, yet deterministic, ways. Wavefront shaping can reverse the effects of scattering to enable deep-tissue microscopy. Such methods require either invasive access to the internal field or the ability to numerically compute it. However, calculating the coherent field on a scale relevant to microscopy remains excessively demanding for consumer hardware. Here we show how a recurrent neural network can mirror Maxwell's equations without training. By harnessing public machine learning infrastructure, such \emph{Scattering Network} can compute the $633\;\textrm{nm}$-wavelength light field throughout a $25\;\textrm{mm}^2$ or $176^3\;μ\textrm{m}^3$ scattering volume. The elimination of the training phase cuts the calculation time to a minimum and, importantly, it ensures a fully deterministic solution, free of any training bias. The integration with an open-source electromagnetic solver enables any researcher with an internet connection to calculate complex light-scattering in volumes that are larger by two orders of magnitude
format Preprint
id arxiv_https___arxiv_org_abs_2208_01118
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle A physics-defined recurrent neural network to compute coherent light wave scattering on the millimetre scale
Valantinas, Laurynas
Vettenburg, Tom
Computational Physics
Optics
Heterogeneous materials such as biological tissue scatter light in random, yet deterministic, ways. Wavefront shaping can reverse the effects of scattering to enable deep-tissue microscopy. Such methods require either invasive access to the internal field or the ability to numerically compute it. However, calculating the coherent field on a scale relevant to microscopy remains excessively demanding for consumer hardware. Here we show how a recurrent neural network can mirror Maxwell's equations without training. By harnessing public machine learning infrastructure, such \emph{Scattering Network} can compute the $633\;\textrm{nm}$-wavelength light field throughout a $25\;\textrm{mm}^2$ or $176^3\;μ\textrm{m}^3$ scattering volume. The elimination of the training phase cuts the calculation time to a minimum and, importantly, it ensures a fully deterministic solution, free of any training bias. The integration with an open-source electromagnetic solver enables any researcher with an internet connection to calculate complex light-scattering in volumes that are larger by two orders of magnitude
title A physics-defined recurrent neural network to compute coherent light wave scattering on the millimetre scale
topic Computational Physics
Optics
url https://arxiv.org/abs/2208.01118