On Computing a Center Persistence Diagram
Abstract
Throughout this paper, a persistence diagram is composed of a set of planar points (each corresponding to a topological feature) above the line , as well as the line itself, i.e., . Given a set of persistence diagrams , for the data reduction purpose, one way to summarize their topological features is to compute the {\em center} of them first under the bottleneck distance. We consider two discrete versions and one continuous version. For technical reasons, we first focus on the case when 's are all the same (i.e., all have the same size ), and the problem is to compute a center point set under the bottleneck matching distance. We show, by a non-trivial reduction from the Planar 3D-Matching problem, that this problem is NP-hard even when diagrams are given. This implies that the general center problem for persistence diagrams under the bottleneck distance, when 's possibly have different sizes, is also NP-hard when . On the positive side, we show that this problem is polynomially solvable when and admits a factor-2 approximation for . These positive results hold for any metric when 's are point sets of the same size, and also hold for the case when 's have different sizes in the metric (i.e., for the Center Persistence Diagram problem). This is the best possible in polynomial time for the Center Persistence Diagram under the bottleneck distance unless P = NP. All these results hold for both of the discrete versions as well as the continuous version; in fact, the NP-hardness and approximation results also hold under the Wasserstein distance for the continuous version.
Cite
@article{arxiv.1910.01753,
title = {On Computing a Center Persistence Diagram},
author = {Yuya Higashikawa and Naoki Katoh and Guohui Lin and Eiji Miyano and Suguru Tamaki and Junichi Teruyama and Binhai Zhu},
journal= {arXiv preprint arXiv:1910.01753},
year = {2020}
}
Comments
16 pages, 7 figures