The Phase Transition of Discrepancy in Random Hypergraphs

Abstract

Motivated by the Beck-Fiala conjecture, we study the discrepancy problem in two related models of random hypergraphs on n vertices and m edges. In the first (edge-independent) model, a random hypergraph H1 is constructed by fixing a parameter p and allowing each of the n vertices to join each of the m edges independently with probability p. In the parameter range in which pn → ∞ and pm → ∞, we show that with high probability (w.h.p.) H1 has discrepancy at least (2-n/m pn) when m = O(n), and at least (pn γ ) when m n, where γ = \ m/n, pn\. In the second (edge-dependent) model, d is fixed and each vertex of H2 independently joins exactly d edges uniformly at random. We obtain analogous results for this model by generalizing the techniques used for the edge-independent model with p=d/m. Namely, for d → ∞ and dn/m → ∞, we prove that w.h.p. H2 has discrepancy at least (2-n/m dn/m) when m = O(n), and at least ((dn/m) γ) when m n, where γ =\m/n, dn/m\. Furthermore, we obtain nearly matching asymptotic upper bounds on the discrepancy in both models (when p=d/m), in the dense regime of m n. Specifically, we apply the partial colouring lemma of Lovett and Meka to show that w.h.p. H1 and H2 each have discrepancy O( dn/m (m/n)), provided d → ∞, d n/m → ∞ and m n. This result is algorithmic, and together with the work of Bansal and Meka characterizes how the discrepancy of each random hypergraph model transitions from (d) to o(d) as m varies from m=(n) to m n.