English

1-factorizations of pseudorandom graphs

Combinatorics 2018-04-09 v1 Discrete Mathematics

Abstract

A 11-factorization of a graph GG is a collection of edge-disjoint perfect matchings whose union is E(G)E(G). A trivial necessary condition for GG to admit a 11-factorization is that V(G)|V(G)| is even and GG is regular; the converse is easily seen to be false. In this paper, we consider the problem of finding 11-factorizations of regular, pseudorandom graphs. Specifically, we prove that an (n,d,λ)(n,d,\lambda)-graph GG (that is, a dd-regular graph on nn vertices whose second largest eigenvalue in absolute value is at most λ\lambda) admits a 11-factorization provided that nn is even, C0dn1C_0\leq d\leq n-1 (where C0C_0 is a universal constant), and λd1o(1)\lambda\leq d^{1-o(1)}. In particular, since (as is well known) a typical random dd-regular graph Gn,dG_{n,d} is such a graph, we obtain the existence of a 11-factorization in a typical Gn,dG_{n,d} for all C0dn1C_0\leq d\leq n-1, thereby extending to all possible values of dd results obtained by Janson, and independently by Molloy, Robalewska, Robinson, and Wormald for fixed dd. Moreover, we also obtain a lower bound for the number of distinct 11-factorizations of such graphs GG which is off by a factor of 22 in the base of the exponent from the known upper bound. This lower bound is better by a factor of 2nd/22^{nd/2} than the previously best known lower bounds, even in the simplest case where GG is the complete graph. Our proofs are probabilistic and can be easily turned into polynomial time (randomized) algorithms.

Keywords

Cite

@article{arxiv.1803.10361,
  title  = {1-factorizations of pseudorandom graphs},
  author = {Asaf Ferber and Vishesh Jain},
  journal= {arXiv preprint arXiv:1803.10361},
  year   = {2018}
}
R2 v1 2026-06-23T01:07:05.460Z