English

A bandwidth theorem for approximate decompositions

Combinatorics 2018-11-12 v2

Abstract

We provide a degree condition on a regular nn-vertex graph GG which ensures the existence of a near optimal packing of any family H\mathcal H of bounded degree nn-vertex kk-chromatic separable graphs into GG. In general, this degree condition is best possible. Here a graph is separable if it has a sublinear separator whose removal results in a set of components of sublinear size. Equivalently, the separability condition can be replaced by that of having small bandwidth. Thus our result can be viewed as a version of the bandwidth theorem of B\"ottcher, Schacht and Taraz in the setting of approximate decompositions. More precisely, let δk\delta_k be the infimum over all δ1/2\delta\ge 1/2 ensuring an approximate KkK_k-decomposition of any sufficiently large regular nn-vertex graph GG of degree at least δn\delta n. Now suppose that GG is an nn-vertex graph which is close to rr-regular for some r(δk+o(1))nr \ge (\delta_k+o(1))n and suppose that H1,,HtH_1,\dots,H_t is a sequence of bounded degree nn-vertex kk-chromatic separable graphs with ie(Hi)(1o(1))e(G)\sum_i e(H_i) \le (1-o(1))e(G). We show that there is an edge-disjoint packing of H1,,HtH_1,\dots,H_t into GG. If the HiH_i are bipartite, then r(1/2+o(1))nr\geq (1/2+o(1))n is sufficient. In particular, this yields an approximate version of the tree packing conjecture in the setting of regular host graphs GG of high degree. Similarly, our result implies approximate versions of the Oberwolfach problem, the Alspach problem and the existence of resolvable designs in the setting of regular host graphs of high degree.

Keywords

Cite

@article{arxiv.1712.04562,
  title  = {A bandwidth theorem for approximate decompositions},
  author = {Padraig Condon and Jaehoon Kim and Daniela Kühn and Deryk Osthus},
  journal= {arXiv preprint arXiv:1712.04562},
  year   = {2018}
}

Comments

Final version, to appear in the Proceedings of the London Mathematical Society

R2 v1 2026-06-22T23:16:21.231Z