Abstract
We show how to adjust a very nice coupling argument due to McDiarmid in order to prove/reprove in a novel way results concerning Hamilton cycles in various models of random graph and hypergraphs. In particular, we firstly show that for $k\geq 3$, if $pn^{k-1}/\log n$ tends to infinity, then a random $k$-uniform hypergraph on $n$ vertices, with edge probability $p$, with high probability (w.h.p.) contains a loose Hamilton cycle, provided that $(k-1)|n$. This generalizes results of Frieze, Dudek and Frieze, and reproves a result of Dudek, Frieze, Loh and Speiss. Secondly, we show that there exists $K>0$ such for every $p\geq (K\log n)/n$ the following holds: Let $G_{n,p}$ be a random graph on $n$ vertices with edge probability $p$, and suppose that its edges are being colored with $n$ colors uniformly at random. Then, w.h.p. the resulting graph contains a Hamilton cycle with for which all the colors appear (a rainbow Hamilton cycle). Bal and Frieze proved the latter statement for graphs on an even number of vertices, where for odd $n$ their $p$ was $\omega((\log n)/n)$. Lastly, we show that for $p=(1+o(1))(\log n)/n$, if we randomly color the edge set of a random directed graph $D_{n,p}$ with $(1+o(1))n$ colors, then w.h.p. one can find a rainbow Hamilton cycle where all the edges are directed in the same way.
Highlights
In this paper we show how to adjust a very nice coupling argument due to McDiarmid [7] in order to prove/reprove problems related to the existence of Hamilton cycles in various random graphs/hypergraphs models
We show how to adjust a very nice coupling argument due to McDiarmid in order to prove/reprove in a novel way results concerning Hamilton cycles in various models of random graphs and hypergraphs
We firstly show that for k 3, if pnk−1/ log n tends to infinity, a random k-uniform hypergraph on n vertices, with edge probability p, with high probability (w.h.p.) contains a loose Hamilton cycle, provided that (k − 1)|n
Summary
In this paper we show how to adjust a very nice coupling argument due to McDiarmid [7] in order to prove/reprove problems related to the existence of Hamilton cycles in various random graphs/hypergraphs models. There exists a constant c > 0 such that for p (c log n)/n the following holds lim Pr Hn(3,p) contains a loose Hamilton cycle = 1. Another problem we handle with is the problem of finding a rainbow Hamilton cycle in a randomly edge-colored random graph. Bal and Frieze [1] showed that for some constant K > 0, if p (K log n)/n, the Gn(n, p) w.h.p. contains a rainbow Hamilton cycle, provided that n is even. Frieze and Loh [5] proved that for p = (1 + ε)(log n)/n and for c = n + Θ(n/ log log n), a graph Gcn,p w.h.p. contains a rainbow Hamilton cycle. Dnc,p w.h.p. contains a rainbow Hamilton cycle
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