Stopping Times of Random Walks on a Hypercube
Abstract
A random walk on a N-dimensional hypercube is a discrete time stochastic process whose state space is the set \-1,+1\N, which has uniform probability of reaching any neighbour state, and probability zero of reaching a non-neighbour state, in one step. This random walk is often studied as a process associated with the Ehrenfest Urn Model. This paper aims to present results about the time that such random walk takes to self-intersect and to return to a set of states. We also present results about the time that the random walk on a hypercube takes to visit a given set and a random set of states. Asymptotic distributions and bounds are presented for these times. The coupling of random walks is widely used as a tool to prove the results.
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