English

Connectivity and tree structure in finite graphs

Combinatorics 2014-09-02 v5

Abstract

Considering systems of separations in a graph that separate every pair of a given set of vertex sets that are themselves not separated by these separations, we determine conditions under which such a separation system contains a nested subsystem that still separates those sets and is invariant under the automorphisms of the graph. As an application, we show that the kk-blocks -- the maximal vertex sets that cannot be separated by at most kk vertices -- of a graph GG live in distinct parts of a suitable tree-decomposition of GG of adhesion at most kk, whose decomposition tree is invariant under the automorphisms of GG. This extends recent work of Dunwoody and Kr\"on and, like theirs, generalizes a similar theorem of Tutte for k=2k=2. Under mild additional assumptions, which are necessary, our decompositions can be combined into one overall tree-decomposition that distinguishes, for all kk simultaneously, all the kk-blocks of a finite graph.

Keywords

Cite

@article{arxiv.1105.1611,
  title  = {Connectivity and tree structure in finite graphs},
  author = {Johannes Carmesin and Reinhard Diestel and Fabian Hundertmark and Maya Stein},
  journal= {arXiv preprint arXiv:1105.1611},
  year   = {2014}
}

Comments

31 pages

R2 v1 2026-06-21T18:04:25.085Z