English

Revisiting Graph Persistence for Updates and Efficiency

Computational Geometry 2023-05-12 v2 Algebraic Topology

Abstract

It is well known that ordinary persistence on graphs can be computed more efficiently than the general persistence. Recently, it has been shown that zigzag persistence on graphs also exhibits similar behavior. Motivated by these results, we revisit graph persistence and propose efficient algorithms especially for local updates on filtrations, similar to what is done in ordinary persistence for computing the vineyard. We show that, for a filtration of length mm, (i) switches (transpositions) in ordinary graph persistence can be done in O(logm)O(\log m) time; (ii) zigzag persistence on graphs can be computed in O(mlogm)O(m\log m) time, which improves a recent O(mlog4n)O(m\log^4n) time algorithm assuming nn, the size of the union of all graphs in the filtration, satisfies nΩ(mε)n\in\Omega({m^\varepsilon}) for any fixed 0<ε<10<\varepsilon<1; (iii) open-closed, closed-open, and closed-closed bars in dimension 00 for graph zigzag persistence can be updated in O(logm)O(\log m) time, whereas the open-open bars in dimension 00 and closed-closed bars in dimension 11 can be done in O(mlogm)O(\sqrt{m}\,\log m) time.

Keywords

Cite

@article{arxiv.2302.12796,
  title  = {Revisiting Graph Persistence for Updates and Efficiency},
  author = {Tamal K. Dey and Tao Hou and Salman Parsa},
  journal= {arXiv preprint arXiv:2302.12796},
  year   = {2023}
}
R2 v1 2026-06-28T08:49:02.727Z