English

Extension Complexity, MSO Logic, and Treewidth

Data Structures and Algorithms 2023-06-22 v9 Computational Complexity

Abstract

We consider the convex hull Pφ(G)P_{\varphi}(G) of all satisfying assignments of a given MSO formula φ\varphi on a given graph GG. We show that there exists an extended formulation of the polytope Pφ(G)P_{\varphi}(G) that can be described by f(φ,τ)nf(|\varphi|,\tau)\cdot n inequalities, where nn is the number of vertices in GG, τ\tau is the treewidth of GG and ff is a computable function depending only on φ\varphi and τ.\tau. In other words, we prove that the extension complexity of Pφ(G)P_{\varphi}(G) is linear in the size of the graph GG, with a constant depending on the treewidth of GG and the formula φ\varphi. This provides a very general yet very simple meta-theorem about the extension complexity of polytopes related to a wide class of problems and graphs. As a corollary of our main result, we obtain an analogous result % for the weaker MSO1_1 logic on the wider class of graphs of bounded cliquewidth. Furthermore, we study our main geometric tool which we term the glued product of polytopes. While the glued product of polytopes has been known since the '90s, we are the first to show that it preserves decomposability and boundedness of treewidth of the constraint matrix. This implies that our extension of Pφ(G)P_\varphi(G) is decomposable and has a constraint matrix of bounded treewidth; so far only few classes of polytopes are known to be decomposable. These properties make our extension useful in the construction of algorithms.

Keywords

Cite

@article{arxiv.1507.04907,
  title  = {Extension Complexity, MSO Logic, and Treewidth},
  author = {Petr Kolman and Martin Koutecký and Hans Raj Tiwary},
  journal= {arXiv preprint arXiv:1507.04907},
  year   = {2023}
}

Comments

Final version accepted by DMTCS

R2 v1 2026-06-22T10:13:47.712Z