Fast Bidirectional Probability Estimation in Markov Models

We develop a new bidirectional algorithm for estimating Markov chain multi-step transition probabilities: given a Markov chain, we want to estimate the probability of hitting a given target state in null steps after starting from a given source distribution. Given the target state t, we use a (reverse) local power iteration to construct an'expanded target distribution', which has the same mean as the quantity we want to estimate, but a smaller variance - this can then be sampled efficiently by a Monte Carlo algorithm. Our method extends to any Markov chain on a discrete (finite or countable) state-space, and can be extended to compute functions of multi-step transition probabilities such as PageRank, graph diffusions, hitting/return times, etc. Our main result is that in'sparse' Markov Chains - wherein the number of transitions between states is comparable to the number of states - the running time of our algorithm for a uniform-random target node is order-wise smaller than Monte Carlo and power iteration based algorithms; in particular, our method can estimate a probability p using only O (1/ p) running time.