B0356
Title: Autoregressive density modeling with the Gaussian process mixture transition distribution
Authors: Matthew Heiner - Brigham Young University (United States) [presenting]
Athanasios Kottas - University of California at Santa Cruz (United States)
Abstract: A mixture model is developed for transition density approximation, together with soft model selection, in the presence of noisy and heterogeneous nonlinear dynamics. The model builds on the Gaussian mixture transition distribution (MTD) model for continuous state spaces, extending component means with nonlinear functions that are modeled using Gaussian process (GP) priors. The resulting model flexibly captures nonlinear and heterogeneous lag dependence when several mixture components are active, identifies low-order nonlinear dependence while inferring relevant lags when few components are active, and averages over multiple and competing single-lag models to quantify/propagate uncertainty. Sparsity-inducing priors on the mixture weights aid in selecting a subset of active lags. The hierarchical model specification follows conventions for both GP regression and MTD models, admitting a convenient Gibbs sampling scheme for posterior inference. We demonstrate the properties of the proposed model with two simulated and two real-time series, emphasizing approximation of lag-dependent transition densities and model selection. In most cases, the model decisively recovers important features. The proposed model provides a simple, yet flexible framework that preserves useful and distinguishing characteristics of the MTD model class.
