A combinatorial perspective on the Kemeny constant and more
Abstract
Let $M$ be an irreducible transition matrix on a finite state space $V$. For a Markov chain $C=(C_k,k\geq 0)$ with transition matrix $M$, let $\tau^{\geq 1}_u$ denote the first positive hitting time of $u$ by $C$, and $\rho$ the unique invariant measure of $M$. Kemeny proved that if $X$ is sampled according to $\rho$ independently of $C$, the expected value of the first positive hitting time of $X$ by $C$ does not depend on the starting state of the chain: all the values $(E(\tau^{\geq 1}_X~|~C_0=u), u \in V)$ are equal. \par In this paper, we show that this property follows from a more general result: the generating function $\sum_{v\in V}E(x^{\tau_v^{\geq 1}}~|~C_0=u)\det(Id-xM^{(v)})$ is independent of the starting state $u$, where $M^{(v)}$ is obtained from $M$ by deleting the row and column corresponding to the state $v$. The factors appearing in this generating function are: first, the probability generating function of $\tau^{\geq 1}_v$, and second, the sequence of determinants $(det(Id-xM^{(v)}),v\in V),$ which, for $x=1$, is known to be proportional to the invariant measure $(\rho_u,u\in V)$. From this property, we deduce several further results, including relations involving higher moments of $\tau_X^{\geq 1}$, which are of independent interest.