English

Sparse Kneser graphs are Hamiltonian

Combinatorics 2021-08-11 v3 Discrete Mathematics

Abstract

For integers k1k\geq 1 and n2k+1n\geq 2k+1, the Kneser graph K(n,k)K(n,k) is the graph whose vertices are the kk-element subsets of {1,,n}\{1,\ldots,n\} and whose edges connect pairs of subsets that are disjoint. The Kneser graphs of the form K(2k+1,k)K(2k+1,k) are also known as the odd graphs. We settle an old problem due to Meredith, Lloyd, and Biggs from the 1970s, proving that for every k3k\geq 3, the odd graph K(2k+1,k)K(2k+1,k) has a Hamilton cycle. This and a known conditional result due to Johnson imply that all Kneser graphs of the form K(2k+2a,k)K(2k+2^a,k) with k3k\geq 3 and a0a\geq 0 have a Hamilton cycle. We also prove that K(2k+1,k)K(2k+1,k) has at least 22k62^{2^{k-6}} distinct Hamilton cycles for k6k\geq 6. Our proofs are based on a reduction of the Hamiltonicity problem in the odd graph to the problem of finding a spanning tree in a suitably defined hypergraph on Dyck words.

Keywords

Cite

@article{arxiv.1711.01636,
  title  = {Sparse Kneser graphs are Hamiltonian},
  author = {Torsten Mütze and Jerri Nummenpalo and Bartosz Walczak},
  journal= {arXiv preprint arXiv:1711.01636},
  year   = {2021}
}
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