In computational statistics, reversible-jump Markov chain Monte Carlo is an extension to standard Markov chain Monte Carlo (MCMC) methodology, introduced by Peter Green, which allows simulation (the creation of samples) of the posterior distribution on spaces of varying dimensions.[1] Thus, the simulation is possible even if the number of parameters in the model is not known. The "jump" refers to the switching from one parameter space to another during the running of the chain. RJMCMC is useful to compare models of different dimension to see which one fits the data best. It is also useful for predictions of new data points, because we do not need to choose and fix a model, RJMCMC can directly predict the new values for all the models at the same time. Models that suit the data best will be chosen more frequently then the poorer ones.
Details on the RJMCMC process
editLet be a model indicator and the parameter space whose number of dimensions depends on the model . The model indication need not be finite. The stationary distribution is the joint posterior distribution of that takes the values .
The proposal can be constructed with a mapping of and , where is drawn from a random component with density on . The move to state can thus be formulated as
The function
must be one to one and differentiable, and have a non-zero support:
so that there exists an inverse function
that is differentiable. Therefore, the and must be of equal dimension, which is the case if the dimension criterion
is met where is the dimension of . This is known as dimension matching.
If then the dimensional matching condition can be reduced to
with
The acceptance probability will be given by
where denotes the absolute value and is the joint posterior probability
where is the normalising constant.
Software packages
editThere is an experimental RJ-MCMC tool available for the open source BUGs package.
The Gen probabilistic programming system automates the acceptance probability computation for user-defined reversible jump MCMC kernels as part of its Involution MCMC feature.
References
edit- ^ Green, P.J. (1995). "Reversible Jump Markov Chain Monte Carlo Computation and Bayesian Model Determination". Biometrika. 82 (4): 711–732. CiteSeerX 10.1.1.407.8942. doi:10.1093/biomet/82.4.711. JSTOR 2337340. MR 1380810.