Tree formulas, mean first passage times and Kemeny's constant of a Markov chain

Abstract

In this paper, we aim to provide probabilistic and combinatorial insights into tree formulas for the Green function and hitting probabilities of Markov chains on a finite state space. These tree formulas are closely related to loop-erased random walks by Wilson's algorithm for random spanning trees, and to mixing times by the Markov chain tree theorem. Let mij be the mean first passage time from i to j for an irreducible chain with finite state space S and transition matrix (pij; i, j ∈ S). It is well-known that mjj = 1/πj = (1)/j, where π is the stationary distribution for the chain, j is the tree sum, over nn-2 trees t spanning S with root j and edges i → k directed to j, of the tree product Πi → k ∈ t pik, and (1):= Σj ∈ S j. Chebotarev and Agaev derived further results from Kirchhoff's matrix tree theorem. We deduce that for i j, mij = ij/j, where ij is the sum over the same set of nn-2 spanning trees of the same tree product as for j, except that in each product the factor pkj is omitted where k = k(i,j,t) is the last state before j in the path from i to j in t. It follows that Kemeny's constant Σj ∈ S mij/mjj equals to (2)/(1), where (r) is the sum, over all forests f labeled by S with r trees, of the product of pij over edges i → j of t. We show that these results can be derived without appeal to the matrix tree theorem. A list of relevant literature is also reviewed.