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Autori principali: Corrias, Marco, Franceschi, Giada, Riva, Michele, Tampieri, Alberto, Föttinger, Karin, Diebold, Ulrike, Pock, Thomas, Franchini, Cesare
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2505.08843
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author Corrias, Marco
Franceschi, Giada
Riva, Michele
Tampieri, Alberto
Föttinger, Karin
Diebold, Ulrike
Pock, Thomas
Franchini, Cesare
author_facet Corrias, Marco
Franceschi, Giada
Riva, Michele
Tampieri, Alberto
Föttinger, Karin
Diebold, Ulrike
Pock, Thomas
Franchini, Cesare
contents Experimentally acquired microscopy images are unavoidably affected by the presence of noise and other unwanted signals, which degrade their quality and might hide relevant features. With the recent increase in image acquisition rate, modern denoising and restoration solutions become necessary. This study focuses on image decomposition and denoising of microscopy images through a workflow based on total variation (TV), addressing images obtained from various microscopy techniques, including atomic force microscopy (AFM), scanning tunneling microscopy (STM), and scanning electron microscopy (SEM). Our approach consists in restoring an image by extracting its unwanted signal components and subtracting them from the raw one, or by denoising it. We evaluate the performance of TV-$L^1$, Huber-ROF, and TGV-$L^1$ in achieving this goal in distinct study cases. Huber-ROF proved to be the most flexible one, while TGV-$L^1$ is the most suitable for denoising. Our results suggest a wider applicability of this method in microscopy, restricted not only to STM, AFM, and SEM images. The Python code used for this study is publicly available as part of AiSurf. It is designed to be integrated into experimental workflows for image acquisition or can be used to denoise previously acquired images.
format Preprint
id arxiv_https___arxiv_org_abs_2505_08843
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Total Variation-Based Image Decomposition and Denoising for Microscopy Images
Corrias, Marco
Franceschi, Giada
Riva, Michele
Tampieri, Alberto
Föttinger, Karin
Diebold, Ulrike
Pock, Thomas
Franchini, Cesare
Image and Video Processing
Materials Science
Computer Vision and Pattern Recognition
Experimentally acquired microscopy images are unavoidably affected by the presence of noise and other unwanted signals, which degrade their quality and might hide relevant features. With the recent increase in image acquisition rate, modern denoising and restoration solutions become necessary. This study focuses on image decomposition and denoising of microscopy images through a workflow based on total variation (TV), addressing images obtained from various microscopy techniques, including atomic force microscopy (AFM), scanning tunneling microscopy (STM), and scanning electron microscopy (SEM). Our approach consists in restoring an image by extracting its unwanted signal components and subtracting them from the raw one, or by denoising it. We evaluate the performance of TV-$L^1$, Huber-ROF, and TGV-$L^1$ in achieving this goal in distinct study cases. Huber-ROF proved to be the most flexible one, while TGV-$L^1$ is the most suitable for denoising. Our results suggest a wider applicability of this method in microscopy, restricted not only to STM, AFM, and SEM images. The Python code used for this study is publicly available as part of AiSurf. It is designed to be integrated into experimental workflows for image acquisition or can be used to denoise previously acquired images.
title Total Variation-Based Image Decomposition and Denoising for Microscopy Images
topic Image and Video Processing
Materials Science
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2505.08843