Abstract
Typically, the first step in carrying out predictions is to develop an inductive model. In many instances, the best model is used, and it is often selected based on certain relevant criteria that may possibly ignore some of the model uncertainties. The Bayesian approach to model selection uses a weighted average of a class of models thereby overcoming some of the uncertainties associated with selecting the best model. This approach is referred to in the literature as the Bayesian Model Averaging (BMA) approach. It turns out that this approach has significant overlap with the theory of Algorithmic Probability (ALP) developed by R. J. Solomonoff in the early 1960s. The purpose of this article is to first highlight this connection by applying ALP to a set of nested stationary autoregressive time series models, and to give an algorithm to compute "relative weights" of models. This reveals, although empirically, a model weight that can be compared with the Schwarz Bayesian Selection criterion (BIC or SIC). We then develop an elementary algorithm of the Monte Carlo type to evaluate multidimensional integrals over stability domains, and use it to compute what we call the "trimmed weights".