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Autore principale: Sokolov, Igor
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2403.16230
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author Sokolov, Igor
author_facet Sokolov, Igor
contents Atomic force microscopy (AFM or SPM) imaging is one of the best matches with machine learning (ML) analysis among microscopy techniques. The digital format of AFM images allows for direct utilization in ML algorithms without the need for additional processing. Additionally, AFM enables the simultaneous imaging of distributions of over a dozen different physicochemical properties of sample surfaces, a process known as multidimensional imaging. While this wealth of information can be challenging to analyze using traditional methods, ML provides a seamless approach to this task. However, the relatively slow speed of AFM imaging poses a challenge in applying deep learning methods broadly used in image recognition. This Prospective is focused on ML recognition/classification when using a relatively small number of AFM images, small database. We discuss ML methods other than popular deep-learning neural networks. The described approach has already been successfully used to analyze and classify the surfaces of biological cells. It can be applied to recognize medical images, specific material processing, in forensic studies, even to identify the authenticity of arts. A general template for ML analysis specific to AFM is suggested, with a specific example of the identification of cell phenotype. Special attention is given to the analysis of the statistical significance of the obtained results, an important feature that is often overlooked in papers dealing with machine learning. A simple method for finding statistical significance is also described.
format Preprint
id arxiv_https___arxiv_org_abs_2403_16230
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle On machine learning analysis of atomic force microscopy images for image classification, sample surface recognition
Sokolov, Igor
Biological Physics
Artificial Intelligence
Instrumentation and Detectors
Medical Physics
92C05, 92C55, 92C10, 92C50
J.2; J.3; I.2; I.5
Atomic force microscopy (AFM or SPM) imaging is one of the best matches with machine learning (ML) analysis among microscopy techniques. The digital format of AFM images allows for direct utilization in ML algorithms without the need for additional processing. Additionally, AFM enables the simultaneous imaging of distributions of over a dozen different physicochemical properties of sample surfaces, a process known as multidimensional imaging. While this wealth of information can be challenging to analyze using traditional methods, ML provides a seamless approach to this task. However, the relatively slow speed of AFM imaging poses a challenge in applying deep learning methods broadly used in image recognition. This Prospective is focused on ML recognition/classification when using a relatively small number of AFM images, small database. We discuss ML methods other than popular deep-learning neural networks. The described approach has already been successfully used to analyze and classify the surfaces of biological cells. It can be applied to recognize medical images, specific material processing, in forensic studies, even to identify the authenticity of arts. A general template for ML analysis specific to AFM is suggested, with a specific example of the identification of cell phenotype. Special attention is given to the analysis of the statistical significance of the obtained results, an important feature that is often overlooked in papers dealing with machine learning. A simple method for finding statistical significance is also described.
title On machine learning analysis of atomic force microscopy images for image classification, sample surface recognition
topic Biological Physics
Artificial Intelligence
Instrumentation and Detectors
Medical Physics
92C05, 92C55, 92C10, 92C50
J.2; J.3; I.2; I.5
url https://arxiv.org/abs/2403.16230