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Autores principales: Kemme, Aurelie Jodelle, Agyingi, Collins Amburo
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2505.06583
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author Kemme, Aurelie Jodelle
Agyingi, Collins Amburo
author_facet Kemme, Aurelie Jodelle
Agyingi, Collins Amburo
contents Persistent Homology (PH) is a fundamental tool in computational topology, designed to uncover the intrinsic geometric and topological features of data across multiple scales. Originating within the broader framework of Topological Data Analysis (TDA), PH has found diverse applications ranging from protein structure and knot analysis to financial domains such as Bitcoin behaviour and stock market dynamics. Despite its growing relevance, there remains a lack of accessible resources that bridge the gap between theoretical foundations and practical implementation for beginners. This paper offers a clear and comprehensive introduction to persistent homology, guiding readers from core concepts to real-world applications. Specifically, we illustrate the methodology through the analysis of a 3-1 supercoiled DNA structure. The paper is tailored for readers without prior exposure to algebraic topology, aiming to demystify persistent homology and foster its broader adoption in data analysis tasks.
format Preprint
id arxiv_https___arxiv_org_abs_2505_06583
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Persistent Homology: A Pedagogical Introduction with Biological Applications
Kemme, Aurelie Jodelle
Agyingi, Collins Amburo
Algebraic Topology
Persistent Homology (PH) is a fundamental tool in computational topology, designed to uncover the intrinsic geometric and topological features of data across multiple scales. Originating within the broader framework of Topological Data Analysis (TDA), PH has found diverse applications ranging from protein structure and knot analysis to financial domains such as Bitcoin behaviour and stock market dynamics. Despite its growing relevance, there remains a lack of accessible resources that bridge the gap between theoretical foundations and practical implementation for beginners. This paper offers a clear and comprehensive introduction to persistent homology, guiding readers from core concepts to real-world applications. Specifically, we illustrate the methodology through the analysis of a 3-1 supercoiled DNA structure. The paper is tailored for readers without prior exposure to algebraic topology, aiming to demystify persistent homology and foster its broader adoption in data analysis tasks.
title Persistent Homology: A Pedagogical Introduction with Biological Applications
topic Algebraic Topology
url https://arxiv.org/abs/2505.06583