English

On Computing a Center Persistence Diagram

Computational Geometry 2020-02-11 v2

Abstract

Throughout this paper, a persistence diagram P{\cal P} is composed of a set PP of planar points (each corresponding to a topological feature) above the line Y=XY=X, as well as the line Y=XY=X itself, i.e., P=P{(x,y)y=x}{\cal P}=P\cup\{(x,y)|y=x\}. Given a set of persistence diagrams P1,...,Pm{\cal P}_1,...,{\cal P}_m, for the data reduction purpose, one way to summarize their topological features is to compute the {\em center} C{\cal C} 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 Pi|P_i|'s are all the same (i.e., all have the same size nn), and the problem is to compute a center point set CC 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 m=3m=3 diagrams are given. This implies that the general center problem for persistence diagrams under the bottleneck distance, when PiP_i's possibly have different sizes, is also NP-hard when m3m\geq 3. On the positive side, we show that this problem is polynomially solvable when m=2m=2 and admits a factor-2 approximation for m3m\geq 3. These positive results hold for any LpL_p metric when PiP_i's are point sets of the same size, and also hold for the case when PiP_i's have different sizes in the LL_\infty 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.

Keywords

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

R2 v1 2026-06-23T11:34:16.696Z