Stability of Persistent Path Diagrams

arXiv - MATH - Algebraic Topology Pub Date : 2024-06-17 DOI:arxiv-2406.11998

Shen Zhang

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Abstract

In real-world systems, the relationships and connections between components are highly complex. Real systems are often described as networks, where nodes represent objects in the system and edges represent relationships or connections between nodes. With the deepening of research, networks have been endowed with richer structures, such as directed edges, edge weights, and even hyperedges involving multiple nodes. Persistent homology is an algebraic method for analyzing data. It helps us understand the intrinsic structure and patterns of data by tracking the death and birth of topological features at different scale parameters.The original persistent homology is not suitable for directed networks. However, the introduction of path homology established on digraphs solves this problem. This paper studies complex networks represented as weighted digraphs or edge-weighted path complexes and their persistent path homology. We use the homotopy theory of digraphs and path complexes, along with the interleaving property of persistent modules and bottleneck distance, to prove the stability of persistent path diagram with respect to weighted digraphs or edge-weighted path complexes. Therefore, persistent path homology has practical application value.

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持久路径图的稳定性

在现实世界的系统中，各组成部分之间的关系和联系非常复杂。现实系统通常被描述为网络，其中节点代表系统中的对象，边代表节点之间的关系或联系。随着研究的深入，网络被赋予了更丰富的结构，例如有向边缘、边缘权重，甚至涉及多个节点的超边缘。持久同源性是一种分析数据的代数方法。它通过跟踪不同尺度参数下拓扑特征的消亡和诞生，帮助我们理解数据的内在结构和模式。然而，在数图上建立的路径同源性的引入解决了这一问题。本文研究了以加权数图或红格加权路径复数表示的复杂网络及其持久路径同源性。我们利用数图和路径复合体的同调理论，以及持久模块的交织特性和瓶颈距离，证明了持久路径图相对于加权数图或边加权路径复合体的稳定性。因此，持久路径同构具有实际应用价值。

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arXiv - MATH - Algebraic Topology

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