Abstract
We propose a method of spatial prediction using count data that can be reasonably modeled assuming the Conway-Maxwell Poisson distribution (COM-Poisson). The COM-Poisson model is a two parameter generalization of the Poisson distribution that allows for the flexibility needed to model count data that are either over or under-dispersed. The computationally limiting factor of the COM-Poisson distribution is that the likelihood function contains multiple intractable normalizing constants and is not always feasible when using Markov Chain Monte Carlo (MCMC) techniques. Thus, we develop a prior distribution of the parameters associated with the COM-Poisson that avoids the intractable normalizing constant. Also, allowing for spatial random effects induces additional variability that makes it unclear if a spatially correlated Conway-Maxwell Poisson random variable is over or under-dispersed. We propose a computationally efficient hierarchical Bayesian model that addresses these issues. In particular, in our model, the parameters associated with the COM-Poisson do not include spatial random effects (leading to additional variability that changes the dispersion properties of the data), and are then spatially smoothed in subsequent levels of the Bayesian hierarchical model. Furthermore, the spatially smoothed parameters have a simple regression interpretation that facilitates computation. We demonstrate the applicability of our approach using simulated examples, and a motivating application using 2016 US presidential election voting data in the state of Florida obtained from the Florida Division of Elections.
Highlights
In United States presidential elections there are many states that historically vote for the same political party
We propose a method of spatial prediction using count data that can be reasonably modeled assuming the Conway-Maxwell Poisson distribution (COM-Poisson)
We assume conditional independence between the data and the spatial process conditioned on a set of parameters. We refer to this model as Over or Underdispersed Regression for Spatial (OURS) count data
Summary
In United States presidential elections there are many states that historically vote for the same political party. The COM-Poisson provides a promising and flexible approach for performing count data regression This distribution has become widely utilized in a variety of applications and has great practical interest. We show that our modified prior distribution leads to a well defined posterior distribution for the parameters in a COM-Poisson Another contribution of our method is that it is matrix free, which is a growing area in computational statistics (Dai et al, 2020; Yang and Bradley, 2021). The step uses a posterior predictive distribution to a model with functional spatial dependencies defined in the mean This two step procedure shows that we do not need to store a large matrix and nor do we need to compute the intractable normalizing constant in a COM-Poisson, which aids in computational efficiency.
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