Random-step Markov processes
Abstract
We explore two notions of stationary processes. The first is called a random-step Markov process in which the stationary process of states, has a stationary coupling with an independent process on the positive integers, of `random look-back distances'. That is, is independent of the `past states', , and for every positive integer , the probability distribution on the `present', , conditioned on the event and on the past is the same as the probability distribution on conditioned on the `-past', and . A random Markov process is a generalization of a Markov chain of order and has the property that the distribution on the present given the past can be uniformly approximated given the -past, for sufficiently large. Processes with the latter property are called uniform martingales, closely related to the notion of a `continuous -function'. We show that every stationary process on a countable alphabet that is a uniform martingale and is dominated by a finite measure is also a random Markov process and that the random variables and associated coupling can be chosen so that the distribution on the present given the -past and the event is `deterministic': all probabilities are in . In the case of finite alphabets, those random-step Markov processes for which can be chosen with finite expected value are characterized. For stationary processes on an uncountable alphabet, a stronger condition is also considered which is sufficient to imply that a process is a random Markov processes. In addition, a number of examples are given throughout to show the sharpness of the results.
Cite
@article{arxiv.1410.1457,
title = {Random-step Markov processes},
author = {Neal Bushaw and Karen Gunderson and Steven Kalikow},
journal= {arXiv preprint arXiv:1410.1457},
year = {2014}
}
Comments
31 pages