English

Twofold triple systems with cyclic 2-intersecting Gray codes

Combinatorics 2020-08-25 v1

Abstract

Given a combinatorial design D\mathcal{D} with block set B\mathcal{B}, the block-intersection graph (BIG) of D\mathcal{D} is the graph that has B\mathcal{B} as its vertex set, where two vertices B1BB_{1} \in \mathcal{B} and B2BB_{2} \in \mathcal{B} are adjacent if and only if B1B2>0|B_{1} \cap B_{2}| > 0. The ii-block-intersection graph (ii-BIG) of D\mathcal{D} is the graph that has B\mathcal{B} as its vertex set, where two vertices B1BB_{1} \in \mathcal{B} and B2BB_{2} \in \mathcal{B} are adjacent if and only if B1B2=i|B_{1} \cap B_{2}| = i. In this paper several constructions are obtained that start with twofold triple systems (TTSs) with Hamiltonian 22-BIGs and result in larger TTSs that also have Hamiltonian 22-BIGs. These constructions collectively enable us to determine the complete spectrum of TTSs with Hamiltonian 22-BIGs (equivalently TTSs with cyclic 22-intersecting Gray codes) as well as the complete spectrum for TTSs with 22-BIGs that have Hamilton paths (i.e., for TTSs with 22-intersecting Gray codes). In order to prove these spectrum results, we sometimes require ingredient TTSs that have large partial parallel classes; we prove lower bounds on the sizes of partial parallel clasess in arbitrary TTSs, and then construct larger TTSs with both cyclic 22-intersecting Gray codes and parallel classes.

Keywords

Cite

@article{arxiv.1701.07606,
  title  = {Twofold triple systems with cyclic 2-intersecting Gray codes},
  author = {Aras Erzurumluoğlu and David A. Pike},
  journal= {arXiv preprint arXiv:1701.07606},
  year   = {2020}
}
R2 v1 2026-06-22T18:00:56.961Z