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Flipping Odd Matchings in Geometric and Combinatorial Settings

Authors Oswin Aichholzer , Sofia Brenner , Joseph Dorfer , Hung P. Hoang , Daniel Perz , Christian Rieck , Francesco Verciani

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LIPIcs.GD.2025.12.pdf
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ACM Subject Classification
  • Theory of computation → Computational geometry
  • Mathematics of computing → Combinatorial algorithms
Keywords
  • Odd matchings
  • reconfiguration
  • flip graph
  • geometric
  • combinatorial
  • connectivity
  • NP-hardness
  • FPT

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Abstract

We study the problem of reconfiguring odd matchings, that is, matchings that cover all but a single vertex. Our reconfiguration operation is a so-called flip where the unmatched vertex of the first matching gets matched, while consequently another vertex becomes unmatched. We consider two distinct settings: the geometric setting, in which the vertices are points embedded in the plane and all occurring odd matchings are crossing-free, and a combinatorial setting, in which we consider odd matchings in general graphs.
For the latter setting, we provide a complete polynomial time checkable characterization of graphs in which any two odd matchings can be reconfigured into each another. This complements the previously known result that the flip graph is always connected in the geometric setting [Oswin Aichholzer et al., 2025]. In the combinatorial setting, we prove that the diameter of the flip graph, if connected, is linear in the number of vertices. Furthermore, we establish that deciding whether there exists a flip sequence of length k transforming one given matching into another is NP-complete in both the combinatorial and the geometric settings. To prove the latter, we introduce a framework that allows us to transform partial order types into general position with only polynomial overhead. Finally, we demonstrate that when parameterized by the flip distance k, the problem is fixed-parameter tractable (FPT) in the geometric setting when restricted to convex point sets.

Cite As Get BibTex

Oswin Aichholzer, Sofia Brenner, Joseph Dorfer, Hung P. Hoang, Daniel Perz, Christian Rieck, and Francesco Verciani. Flipping Odd Matchings in Geometric and Combinatorial Settings. In 33rd International Symposium on Graph Drawing and Network Visualization (GD 2025). Leibniz International Proceedings in Informatics (LIPIcs), Volume 357, pp. 12:1-12:18, Schloss Dagstuhl – Leibniz-Zentrum für Informatik (2025) https://doi.org/10.4230/LIPIcs.GD.2025.12

Author Details

Oswin Aichholzer
  • Graz University of Technology, Austria
Sofia Brenner
  • University of Kassel, Germany
Joseph Dorfer
  • Graz University of Technology, Austria
Hung P. Hoang
  • TU Wien, Austria
Daniel Perz
  • University of Perugia, Italy
Christian Rieck
  • University of Kassel, Germany
Francesco Verciani
  • University of Kassel, Germany

Funding

  • Brenner, Sofia: German Research Foundation (DFG) grant 522790373.
  • Dorfer, Joseph: Austrian Science Foundation (FWF) grant 10.55776/DOC183.
  • Hoang, Hung P.: Austrian Science Foundation (FWF) project Y 1329 START-Programm.
  • Perz, Daniel: MUR PRIN project 2022ME9Z78 - "NextGRAAL: Next-generation algorithms for constrained GRAph visuALization".
  • Rieck, Christian: German Research Foundation (DFG) grant 522790373.
  • Verciani, Francesco: German Research Foundation (DFG) grant 522790373.

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