Weak lumping of left-invariant random walks on left cosets of finite groups

Abstract

Let G be a finite group and let H be a subgroup of G. The left-invariant random walk driven by a probability measure w on G is the Markov chain in which from any state x ∈ G, the probability of stepping to xg ∈ G is w(g). The initial state is chosen randomly according to a given distribution. The walk is said to lump weakly on left cosets if the induced process on G/H is a time-homogeneous Markov chain. We characterise all the initial distributions and weights w such that the walk is irreducible and lumps weakly on left cosets, and determine all the possible transition matrices of the induced Markov chain. In the case where H is abelian we refine our main results to give a necessary and sufficient condition for weak lumping by an explicit system of linear equations on w, organized by the double cosets HxH. As an application we consider shuffles of a deck of n cards such that repeated observations of the top card form a Markov chain. Such shuffles include the random-to-top shuffle, and also, when the deck is started in a uniform random order, the top-to-random shuffle. We give a further family of examples in which our full theory of weak lumping is needed to verify that the top card sequence is Markov.

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