English

Branch-depth: Generalizing tree-depth of graphs

Combinatorics 2020-11-05 v2

Abstract

We present a concept called the branch-depth of a connectivity function, that generalizes the tree-depth of graphs. Then we prove two theorems showing that this concept aligns closely with the notions of tree-depth and shrub-depth of graphs as follows. For a graph G=(V,E)G = (V,E) and a subset AA of EE we let λG(A)\lambda_G (A) be the number of vertices incident with an edge in AA and an edge in EAE \setminus A. For a subset XX of VV, let ρG(X)\rho_G(X) be the rank of the adjacency matrix between XX and VXV \setminus X over the binary field. We prove that a class of graphs has bounded tree-depth if and only if the corresponding class of functions λG\lambda_G has bounded branch-depth and similarly a class of graphs has bounded shrub-depth if and only if the corresponding class of functions ρG\rho_G has bounded branch-depth, which we call the rank-depth of graphs. Furthermore we investigate various potential generalizations of tree-depth to matroids and prove that matroids representable over a fixed finite field having no large circuits are well-quasi-ordered by the restriction.

Keywords

Cite

@article{arxiv.1903.11988,
  title  = {Branch-depth: Generalizing tree-depth of graphs},
  author = {Matt DeVos and O-joung Kwon and Sang-il Oum},
  journal= {arXiv preprint arXiv:1903.11988},
  year   = {2020}
}

Comments

36 pages, 2 figures. Final version

R2 v1 2026-06-23T08:22:08.714Z