Conditionally specified graphical modeling of stationary multivariate time series

TL;DR

This paper introduces a new class of stationary multivariate time series models called CEStGM, which encode conditional independence using exponential family distributions and an interaction kernel, extending graphical modeling beyond Gaussian assumptions.

Contribution

It develops the concept of conditionally exponential stationary graphical models (CEStGM), establishing their properties, Markov relations, and a sampling algorithm, broadening graphical modeling for non-Gaussian time series.

Findings

CEStGM models encode process-wide conditional independence.

The models are shown to be geometrically mixing.

An approximate Gibbs sampler for CEStGM is developed.

Abstract

Graphical models are ubiquitous for summarizing conditional relations in multivariate data. In many applications involving multivariate time series, it is of interest to learn an interaction graph that treats each individual time series as nodes of the graph, with the presence of an edge between two nodes signifying conditional dependence given the others. Typically, the partial covariance is used as a measure of conditional dependence. However, in many applications, the outcomes may not be Gaussian and/or could be a mixture of different outcomes. For such time series using the partial covariance as a measure of conditional dependence may be restrictive. In this article, we propose a broad class of time series models which are specifically designed to succinctly encode process-wide conditional independence in its parameters. For each univariate component in the time series, we model its conditional distribution with a distribution from the exponential family. We develop a notion of process-wide compatibility under which such conditional specifications can be stitched together to form a well-defined strictly stationary multivariate time series. We call this construction a conditionally exponential stationary graphical model (CEStGM). A central quantity underlying CEStGM is a positive kernel which we call the interaction kernel. Spectral properties of such positive kernel operators constitute a core technical foundation of this work. We establish process-wide local and global Markov properties of CEStGM exploiting a Hammersley-Clifford type decomposition of the interaction kernel. Further, we study various probabilistic properties of CEStGM and show that it is geometrically mixing. An approximate Gibbs sampler is also developed to simulate sample paths of CEStGM.