Tight Staircase Bounds for Cyclic Subsets below Dirac's Threshold

Abstract

Let Cyc(G) denote the number of cyclic subsets in a graph G, which are subsets that induce a Hamiltonian subgraph. Draganić, Keevash and Müyesser recently proved that every regular Dirac graph has Ω(2n) cyclic subsets, resolving a problem of Erdős and Faudree. We determine the sharp asymptotic lower bound throughout the linear range below Dirac's threshold. Let G be an n-vertex d-regular graph with d=Ω(n) and d<n/2, then Cyc(G) (q-o(1))2n/q, where q= nd+1 2. This bound is asymptotically best possible, including the leading coefficient q, as witnessed at the staircase levels by the disjoint union of q equal cliques. Consequently, the optimal exponential rate changes by discrete jumps as d crosses the thresholds n/k, rather than varying smoothly with d. We also prove the optimal exponential rate at the Dirac boundary: every n-vertex n/2-regular graph satisfies Cyc(G) 2(1-o(1))n, which is sharp up to a subexponential factor by Kn/2,n/2.

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