JSM 2021 Online Program

Hidden Markov models (HMM) are a common approach to precipitation modeling, wherein multi-site daily precipitation is assumed to be driven by a latent first-order Markov chain representing underlying weather states. Daily precipitation is specified as a semi-continuous distribution with a point mass at zero for no rainfall and a mixture of Exponential distributions for positive rainfall. We implement variational Bayes as an alternative to the conventionally used Baum-Welch algorithm for parameter estimation in HMMs. Stochastic gradient ascent with block bootstrapping is used to optimize the variational posterior, and a Gaussian copula is constructed to capture the spatial correlations between locations. We test this model using daily precipitation data for the Chesapeake Bay watershed, a large estuarine ecosystem in Eastern USA, for the rainy season months of July to September. Remote sensing data from GPM-IMERG is used for our study, which covers the watershed with 1927 grid points at a 0.1° x 0.1° resolution. Synthetic data generated from the fitted model is able to replicate key spatial and temporal characteristics of historical precipitation data.