English

On Supergraphs Satisfying CMSO Properties

Logic in Computer Science 2023-06-22 v5

Abstract

Let CMSO denote the counting monadic second order logic of graphs. We give a constructive proof that for some computable function ff, there is an algorithm A\mathfrak{A} that takes as input a CMSO sentence φ\varphi, a positive integer tt, and a connected graph GG of maximum degree at most Δ\Delta, and determines, in time f(φ,t)2O(Δt)GO(t)f(|\varphi|,t)\cdot 2^{O(\Delta \cdot t)}\cdot |G|^{O(t)}, whether GG has a supergraph GG' of treewidth at most tt such that GφG'\models \varphi. The algorithmic metatheorem described above sheds new light on certain unresolved questions within the framework of graph completion algorithms. In particular, using this metatheorem, we provide an explicit algorithm that determines, in time f(d)2O(Δd)GO(d)f(d)\cdot 2^{O(\Delta \cdot d)}\cdot |G|^{O(d)}, whether a connected graph of maximum degree Δ\Delta has a planar supergraph of diameter at most dd. Additionally, we show that for each fixed kk, the problem of determining whether GG has an kk-outerplanar supergraph of diameter at most dd is strongly uniformly fixed parameter tractable with respect to the parameter dd. This result can be generalized in two directions. First, the diameter parameter can be replaced by any contraction-closed effectively CMSO-definable parameter p\mathbf{p}. Examples of such parameters are vertex-cover number, dominating number, and many other contraction-bidimensional parameters. In the second direction, the planarity requirement can be relaxed to bounded genus, and more generally, to bounded local treewidth.

Keywords

Cite

@article{arxiv.2001.00758,
  title  = {On Supergraphs Satisfying CMSO Properties},
  author = {Mateus de Oliveira Oliveira},
  journal= {arXiv preprint arXiv:2001.00758},
  year   = {2023}
}
R2 v1 2026-06-23T13:02:06.677Z