Random necklaces require fewer cuts
Abstract
It is known that any open necklace with beads of t types in which the number of beads of each type is divisible by k, can be partitioned by at most (k-1)t cuts into intervals that can be distributed into k collections, each containing the same number of beads of each type. This is tight for all values of k and t. Here, we consider the case of random necklaces, where the number of beads of each type is km. Then the minimum number of cuts required for a ``fair'' partition with the above property is a random variable X(k,t,m). We prove that for fixed k,t, and large m, this random variable is at least (k-1)(t+1)/2 with high probability. For k=2, fixed t, and large m, we determine the asymptotic behavior of the probability that X(2,t,m)=s for all values of s t . We show that this probability is polynomially small when s<(t+1)/2, it is bounded away from zero when s>(t+1)/2, and decays like ( 1/ m) when s=(t+1)/2. We also show that for large t, X(2,t,1) is at most (0.4+o(1))t with high probability and that for large t and large ratio k/ t, X(k,t,1) is o(kt) with high probability.
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