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研究生: 胡全燊
Hu, Chuan-Shen
論文名稱: 數學形態學導出多參數持續同調之層狀結構
Sheaf Structures on the Multi-parameter Persistent Homology Arising from Mathematical Morphology
指導教授: 林俊吉
Lin, Chun-Chi
鍾佑民
Chung, Yu-Min
口試委員: 樂美亨
Yueh, Mei-Heng
崔茂培
Tsui, Mao-Pei
黃楓南
Hwang, Feng-Nan
鍾佑民
Chung, Yu-Min
林俊吉
Lin, Chun-Chi
口試日期: 2022/01/21
學位類別: 博士
Doctor
系所名稱: 數學系
Department of Mathematics
論文出版年: 2022
畢業學年度: 110
語文別: 英文
論文頁數: 178
英文關鍵詞: applied topology, topological data analysis, multi-parameter persistent homology, persistence modules, sheaf theory, cellular sheaves, mathematical morphology, Alexandrov topology, image processing, machine learning
DOI URL: http://doi.org/10.6345/NTNU202200173
論文種類: 學術論文
相關次數: 點閱:167下載:20
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  • Topological Data Analysis (TDA), a fast-growing research topic in applied topology, uses techniques in algebraic topology to capture features from data. Its importance has been discovered in many areas, such as medical image processing, molecular biology, machine learning, and pattern recognition. Persistent homology (PH) is vital in topological data analysis that detects local changes in filtered topological spaces. It measures the robustness and significance of homological objects in spaces' deformation, such as connected components, loops, or higher dimensional voids. In Morse theory, filtered spaces for persistent homology usually rely on a single parameter, such as the sublevel set filtration of height functions. Recently, as a generalization of persistent homology, computational topologists began to be interested in multi-parameter persistent homology. Multi-parameter persistent homology (or multi-parameter persistence) is an algebraic structure established on a multi-parametrized network of topological spaces and has more fruitful geometric information than persistent homology. So far, finding methods to extract features in multi-parameter persistence is still an open and concentrating topic in TDA. Also, examples of multi-parameter filtration are still rare and limited. The three principal contributions of this dissertation are as follows. First, we combined persistent homology features (persistence statistics and persistence curves) and machine learning models for analyzing medical images. We found that adding topological information into machine learning models can improve recognition accuracy and stability. Second, unlike traditional construction for multi-parameter filtrations in Euclidean spaces, we propose a framework for constructing multi-parameter filtrations from digital images through mathematical morphology and discrete geometry. Multi-parameter persistence derived from mathematical morphology is more efficient for computing and contains intuitive geometric attributes of objects, such as the sizes or robustness of local objects in digital images. We involve these features to remove the salt and pepper noise in digital images as an application. Compared with current denoise algorithms, the proposed approach has a more stable accuracy and keeps the topological structures of original data. The third part of this dissertation focuses on using sheaf theory to analyze the lifespans of objects in multi-parameter persistence. The multi-parameter persistence has a natural sheaf structure by equipping the Alexandrov topology on the based partially ordered set. This sheaf structure uncovers the gluing properties of local image regions in the multi-parameter filtration. We referred to these properties as a fingerprint of the filtration and applied them for the character recognition task. Finally, we propose using sheaf operators to define ultrametric norms on local spaces in multi-parameter persistence. Like persistence barcodes, this metric provides finer geometric and topological quantities.

    Abstract i Contents ii List of Tables iv List of Figures v Introduction 1 I Mathematical Preliminaries 9 1 Posets and Alexandrov Topology 10 1.1 Pre-ordered Sets and Posets 10 1.2 Alexandrov Topology 13 2 Algebraic Limits 19 2.1 Direct Limits 19 2.2 Projective Limits 21 3 Mathematical Morphology 24 3.1 Digital Images and Operators 24 3.2 Morphological Opening and Closing 27 3.3 Distance Transform 35 3.4 Cubical Complex Representation for Images 39 4 Sheaf Theory 44 4.1 Presheaves and Sheaves 44 4.2 Morphisms 46 4.3 Base Sheaves 48 4.4 Some Presheaf Operators 52 5 Persistence Modules 57 5.1 Singular Homology 57 5.2 Persistence Homology 59 5.3 Persistence Modules and Multi-parameter Persistence 64 II Sheaves on Morphological Multi-filtrations 66 6 Shift Inclusion and Absorption Property 67 6.1 Shift Inclusion 67 6.2 Shift Inclusion on Special Domains 71 6.3 Shift Inclusion and Order Preserving Property 75 6.4 Discussion on Image Domains 77 6.5 Weak Shift Inclusion 78 7 Morphological Multi-parameter Filtrations 85 7.1 Morphological One-parameter Persistent Homology 85 7.2 Multi-filtrations from Morphological Operators 89 7.3 Bifiltration from Distance Transform and Thresholding 94 8 Cellular Sheaf and Multi-parameter Persistence 99 8.1 Cellular Sheaves 100 8.2 Cellular Sheaves over Prosets 102 8.3 Examples 105 8.4 Local Merging Relations in Topological Spaces 107 8.5 Cellular Sheaves over Convex Sets of Integers 116 8.6 Norms on Cellular Sheaves 118 8.7 Cohomology of Cellular Sheaves 126 III Applications 130 9 Skin Lesion Images Classification 131 9.1 TopoResNet: A TDA-CNN hybrid Model for Skin lesions 131 9.2 Persistence Statistics and Persistence Curves 132 9.3 Architecture of TopoResNet-101 134 9.4 Experiment Results 138 10 Multi-persistence on Digital Images 140 10.1 A Denoising Algorithm for Salt and Pepper noise 140 10.2 Firn Data Analysis 151 11 Local Merging Relations in Digital Images 158 11.1 System of Patches 158 11.2 Local Merging Numbers 160 11.3 One-dimensional Merging Relations 161 11.4 Application on Handwritten Character Recognition 162 12 Conclusion and Future Works 164 12.1 Persistence of Sheaves 165 12.2 Sheaf Cohomology 166 12.3 More Applications on Real Data 166 Bibliography 167

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