Model selection of stochastic simulation algorithm based on generalized divergence measures
Abstract
MCMC methods (Monte Carlo Markov Chain) are a class of methods used to perform simulations per a probability distribution . These methods are often used when we have difficulties to directly sample per a given probability distribution . This distribution is then considered as a target and generates a Markov chain that, when is large we have . These MCMC methods consist of several simulation strategies including the \emph{Independent Sampler (IS)}, the \emph{Random Walk of Metropolis Hastings \small{(RWMH)}}, the \emph{Gibbs sampler}, the \emph{Adaptive Metropolis (AM)} and \emph{Metropolis Within Gibbs (MWG)} strategy. Each of these strategies can generate a Markov chain and is associated with a convergence speed. It is interesting, with a given target law, to compare several simulation strategies for determining the best. Chauveau and Vandekerkhove \cite{Chauv2007} have compared IS and RWMH strategies using the Kullback-Leibler divergence measure. In our article we will compare our five simulation methods already mentioned using generalized divergence measures. These divergence measures are taken in family of -divergence measures \cite{Cichocki2010}, with a parameter . This is the R\'enyi divergence, Tsallis divergence and divergence .
Cite
@article{arxiv.1401.5015,
title = {Model selection of stochastic simulation algorithm based on generalized divergence measures},
author = {Papa Ngom and Badiassiatta Don Bosco Diatta},
journal= {arXiv preprint arXiv:1401.5015},
year = {2014}
}
Comments
23 pages,5 figures