Coupling Markov chains with a common image chain

Abstract

Consider time-homogeneous discrete-time Markov chains X, Y, and Z on countable state spaces, considered as stochastic processes with specified initial distributions. Suppose for maps f and g that (f(Xt))t 0 and (g(Yt))t 0 are both equal in law to Z. We prove that X and Y can be coupled so that (Xt, Yt)t 0 is a homogeneous Markov chain with f(Xt) = g(Yt) for all t 0. Without the assumption that Z is Markov, no such Markov coupling exists in general, even an inhomogeneous one. Moreover, we give an explicit construction of such a coupling, with the additional property that X and Y are conditionally independent given the entire trajectory (f(Xt))t 0. Under the further assumption that X and Y are stationary, we construct a coupling having the above properties that is also stationary. In this case, conditional independence holds for the corresponding two-sided chains indexed by Z (but not necessarily for the one-sided versions). We prove further properties of our couplings in special cases where f or g satisfies the strong lumping condition (also known as Dynkin's condition) or the exact lumping condition (also known as the Pitman-Rogers condition). When f is a strong lumping and g is an exact lumping, we show that our coupling coincides with an intertwining of Markov chains as constructed by Diaconis and Fill.