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Auteurs principaux: Czuchnowski, Jakub, Li, Chuan, Ni, Hongli, Weissbourd, Brandon, Mertz, Jerome
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2512.00225
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author Czuchnowski, Jakub
Li, Chuan
Ni, Hongli
Weissbourd, Brandon
Mertz, Jerome
author_facet Czuchnowski, Jakub
Li, Chuan
Ni, Hongli
Weissbourd, Brandon
Mertz, Jerome
contents Deconvolution is the most widely used aberration correction technique in microscopy, however most techniques assume that the aberrations are the same for each point in the image, which is rarely true. Methods for tracking spatially varying aberrations require burdensome calibration or computation, or require symmetries in the aberration patterns. Here, we expand on existing modal deconvolution methods to demonstrate 3D fluorescence deconvolution in imaging systems that exhibit no simple symmetry. Our method is based on a space-variant generalization of Richardson-Lucy deconvolution that makes use of ZEMAX\textsuperscript{\textregistered}-derived point spread functions without the requirement of guide stars or calibration measurements. We validate the performance of our method by applying it to snapshot multiplane imaging of both bead samples and biological specimens, and show that modal decomposition is a practical solution for deconvolving spatially varying aberrations that do not display clear symmetries.
format Preprint
id arxiv_https___arxiv_org_abs_2512_00225
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle 3D space-variant modal deconvolution with computed point spread functions
Czuchnowski, Jakub
Li, Chuan
Ni, Hongli
Weissbourd, Brandon
Mertz, Jerome
Optics
Deconvolution is the most widely used aberration correction technique in microscopy, however most techniques assume that the aberrations are the same for each point in the image, which is rarely true. Methods for tracking spatially varying aberrations require burdensome calibration or computation, or require symmetries in the aberration patterns. Here, we expand on existing modal deconvolution methods to demonstrate 3D fluorescence deconvolution in imaging systems that exhibit no simple symmetry. Our method is based on a space-variant generalization of Richardson-Lucy deconvolution that makes use of ZEMAX\textsuperscript{\textregistered}-derived point spread functions without the requirement of guide stars or calibration measurements. We validate the performance of our method by applying it to snapshot multiplane imaging of both bead samples and biological specimens, and show that modal decomposition is a practical solution for deconvolving spatially varying aberrations that do not display clear symmetries.
title 3D space-variant modal deconvolution with computed point spread functions
topic Optics
url https://arxiv.org/abs/2512.00225