English

Computing shortest closed curves on non-orientable surfaces

Computational Geometry 2025-09-18 v2 Computational Complexity Geometric Topology

Abstract

We initiate the study of computing shortest non-separating simple closed curves with some given topological properties on non-orientable surfaces. While, for orientable surfaces, any two non-separating simple closed curves are related by a self-homeomorphism of the surface, and computing shortest such curves has been vastly studied, for non-orientable ones the classification of non-separating simple closed curves up to ambient homeomorphism is subtler, depending on whether the curve is one-sided or two-sided, and whether it is orienting or not (whether it cuts the surface into an orientable one). We prove that computing a shortest orienting (weakly) simple closed curve on a non-orientable combinatorial surface is NP-hard but fixed-parameter tractable in the genus of the surface. In contrast, we can compute a shortest non-separating non-orienting (weakly) simple closed curve with given sidedness in gO(1).nlogng^{O(1)}.n\log n time, where gg is the genus and nn the size of the surface. For these algorithms, we develop tools that can be of independent interest, to compute a variation on canonical systems of loops for non-orientable surfaces based on the computation of an orienting curve, and some covering spaces that are essentially quotients of homology covers.

Keywords

Cite

@article{arxiv.2403.11749,
  title  = {Computing shortest closed curves on non-orientable surfaces},
  author = {Denys Bulavka and Éric Colin de Verdière and Niloufar Fuladi},
  journal= {arXiv preprint arXiv:2403.11749},
  year   = {2025}
}
R2 v1 2026-06-28T15:24:09.856Z