A Topological Distance between Multi-fields based on Multi-Dimensional Persistence Diagrams

IF 4.7 1区计算机科学 Q1 COMPUTER SCIENCE, SOFTWARE ENGINEERING IEEE Transactions on Visualization and Computer Graphics Pub Date : 2023-03-06 DOI:10.48550/arXiv.2303.03038

Yashwanth Ramamurthi, A. Chattopadhyay

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Abstract

The problem of computing topological distance between two scalar fields based on Reeb graphs or contour trees has been studied and applied successfully to various problems in topological shape matching, data analysis, and visualization. However, generalizing such results for computing distance measures between two multi-fields based on their Reeb spaces is still in its infancy. Towards this, in the current paper we propose a technique to compute an effective distance measure between two multi-fields by computing a novel multi-dimensional persistence diagram (MDPD) corresponding to each of the (quantized) Reeb spaces. First, we construct a multi-dimensional Reeb graph (MDRG), which is a hierarchical decomposition of the Reeb space into a collection of Reeb graphs. The MDPD corresponding to each MDRG is then computed based on the persistence diagrams of the component Reeb graphs of the MDRG. Our distance measure extends the Wasserstein distance between two persistence diagrams of Reeb graphs to MDPDs of MDRGs. We prove that the proposed measure is a pseudo-metric and satisfies a stability property. Effectiveness of the proposed distance measure has been demonstrated in (i) shape retrieval contest data - SHREC 2010 and (ii) Pt-CO bond detection data from computational chemistry. Experimental results show that the proposed distance measure based on the Reeb spaces has more discriminating power in clustering the shapes and detecting the formation of a stable Pt-CO bond as compared to the similar measures between Reeb graphs.

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基于多维持久化图的多域间拓扑距离

基于Reeb图或等高线树计算两个标量场之间拓扑距离的问题已经被研究并成功地应用于拓扑形状匹配、数据分析和可视化中的各种问题。然而，将这些结果推广到基于Reeb空间计算两个多域之间的距离度量仍然处于起步阶段。为此，本文提出了一种通过计算对应于每个(量化)Reeb空间的新型多维持续图(MDPD)来计算两个多场之间有效距离度量的技术。首先，我们构造了一个多维Reeb图(MDRG)，它是将Reeb空间分层分解为Reeb图的集合。然后根据MDRG的组件Reeb图的持久性图计算每个MDRG对应的MDPD。我们的距离度量将Reeb图的两个持久性图之间的Wasserstein距离扩展到mdrg的mdpd。我们证明了所提出的测度是一个伪测度，并且满足稳定性。所提出的距离度量的有效性已在(i)形状检索竞赛数据(SHREC 2010)和(ii)计算化学的Pt-CO键检测数据中得到证明。实验结果表明，基于Reeb空间的距离测度比基于Reeb图的距离测度在聚类形状和检测稳定Pt-CO键形成方面具有更强的判别能力。

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来源期刊

IEEE Transactions on Visualization and Computer Graphics 工程技术-计算机：软件工程

CiteScore

10.40

自引率

19.20%

发文量

946

审稿时长

4.5 months

期刊介绍： TVCG is a scholarly, archival journal published monthly. Its Editorial Board strives to publish papers that present important research results and state-of-the-art seminal papers in computer graphics, visualization, and virtual reality. Specific topics include, but are not limited to: rendering technologies; geometric modeling and processing; shape analysis; graphics hardware; animation and simulation; perception, interaction and user interfaces; haptics; computational photography; high-dynamic range imaging and display; user studies and evaluation; biomedical visualization; volume visualization and graphics; visual analytics for machine learning; topology-based visualization; visual programming and software visualization; visualization in data science; virtual reality, augmented reality and mixed reality; advanced display technology, (e.g., 3D, immersive and multi-modal displays); applications of computer graphics and visualization.