Universality of Cutoff for Riffle Shuffling

Abstract

A Gilbert-Shannon-Reeds (GSR) shuffle is performed on a deck of N cards by cutting the top n Bin(N,1/2) cards and interleaving the two resulting piles uniformly at random. The celebrated "Seven shuffles suffice" theorem of [Bayer-Diaconis '92] established cutoff for this Markov chain: to leading order, total variation mixing occurs after precisely 322 N shuffles. Later work of [Lalley '00] and [Sellke '22] extended this result to asymmetric binomial cuts n Bin(N,p) for all p∈ (0,1). These results relied heavily on the binomial condition and many natural chains were left open, including uniformly random cuts and exact bisections. We establish cutoff for riffle shuffles with general pile size distribution. Namely, suppose the cut sizes (n(t))t≥ 1 are IID and the convergence in distribution n(t)/N d μ holds for some probability measure μ on the interval [0,1]. Then the mixing time tmix satisfies tmix/ N Cμ for an explicit constant Cμ. The same result holds for any (deterministic or random) sequence of pile sizes with empirical distribution converging to μ on all macroscopic time intervals (of length ( N)). It also extends to multi-partite shuffles where the deck is cut into more than 2 piles in each step. Qualitatively, we find that the "cold spot" phenomenon identified by [Lalley '00] characterizes the mixing time of riffle shuffling in great generality.

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