Gaussian processes for state space models and change point detection
Turner, Ryan Darby
Rasmussen, Carl Edward
University of Cambridge
Department of Engineering
Doctor of Philosophy (PhD)
MetadataShow full item record
Turner, R. D. (2012). Gaussian processes for state space models and change point detection (Doctoral thesis). https://doi.org/10.17863/CAM.14015
This thesis details several applications of Gaussian processes (GPs) for enhanced time series modeling. We first cover different approaches for using Gaussian processes in time series problems. These are extended to the state space approach to time series in two different problems. We also combine Gaussian processes and Bayesian online change point detection (BOCPD) to increase the generality of the Gaussian process time series methods. These methodologies are evaluated on predictive performance on six real world data sets, which include three environmental data sets, one financial, one biological, and one from industrial well drilling. Gaussian processes are capable of generalizing standard linear time series models. We cover two approaches: the Gaussian process time series model (GPTS) and the autoregressive Gaussian process (ARGP). We cover a variety of methods that greatly reduce the computational and memory complexity of Gaussian process approaches, which are generally cubic in computational complexity. Two different improvements to state space based approaches are covered. First, Gaussian process inference and learning (GPIL) generalizes linear dynamical systems (LDS), for which the Kalman filter is based, to general nonlinear systems for nonparametric system identification. Second, we address pathologies in the unscented Kalman filter (UKF). We use Gaussian process optimization (GPO) to learn UKF settings that minimize the potential for sigma point collapse. We show how to embed mentioned Gaussian process approaches to time series into a change point framework. Old data, from an old regime, that hinders predictive performance is automatically and elegantly phased out. The computational improvements for Gaussian process time series approaches are of even greater use in the change point framework. We also present a supervised framework learning a change point model when change point labels are available in training.
Change point detection, Gaussian processes, Machine learning, UKF, Nonparametric, Time series
I would like to thank Rockwell Collins, formerly DataPath, Inc., which funded my studentship.
This record's DOI: https://doi.org/10.17863/CAM.14015
(C) 2011 Ryan Darby Turner. All rights reserved.