Alan E. Gelfand scite author profile

Stoch~stic substitution, the Gibbs sampler, and the sampling-importance-resampling algorithm can be viewed as three alternative samphng-(or Monte Ca~lo-) bas.ed approaches to the calculation of numerical estimates of marginal probability distributions. The three ap~roache.s w~1l be reviewed, compared, and contrasted in relation to various joint probability structures frequently enc.ountered in applications, In particular, the relevance of the approaches to calculating Bayesian posterior densities for a vanety of structured models will be discussed and illustrated.

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Hierarchical Modeling and Analysis for Spatial Data

Banerjee

2014

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Sampling-Based Approaches to Calculating Marginal Densities

Gelfand

Smith

1990

Journal of the American Statistical Association

1,801

937

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Gaussian Predictive Process Models for Large Spatial Data Sets

et al. 2008

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SummaryWith scientific data available at geocoded locations, investigators are increasingly turning to spatial process models for carrying out statistical inference. Over the last decade, hierarchical models implemented through Markov chain Monte Carlo methods have become especially popular for spatial modelling, given their flexibility and power to fit models that would be infeasible with classical methods as well as their avoidance of possibly inappropriate asymptotics. However, fitting hierarchical spatial models often involves expensive matrix decompositions whose computational complexity increases in cubic order with the number of spatial locations, rendering such models infeasible for large spatial data sets. This computational burden is exacerbated in multivariate settings with several spatially dependent response variables. It is also aggravated when data are collected at frequent time points and spatiotemporal process models are used. With regard to this challenge, our contribution is to work with what we call predictive process models for spatial and spatiotemporal data. Every spatial (or spatiotemporal) process induces a predictive process model (in fact, arbitrarily many of them). The latter models project process realizations of the former to a lower dimensional subspace, thereby reducing the computational burden. Hence, we achieve the flexibility to accommodate non-stationary, non-Gaussian, possibly multivariate, possibly spatiotemporal processes in the context of large data sets. We discuss attractive theoretical properties of these predictive processes. We also provide a computational template encompassing these diverse settings. Finally, we illustrate the approach with simulated and real data sets.

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Hierarchical Nearest-Neighbor Gaussian Process Models for Large Geostatistical Datasets

Datta¹,

Banerjee²,

Finley³

et al. 2016

Journal of the American Statistical Association

541

732

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Spatial process models for analyzing geostatistical data entail computations that become prohibitive as the number of spatial locations become large. This article develops a class of highly scalable nearest-neighbor Gaussian process (NNGP) models to provide fully model-based inference for large geostatistical datasets. We establish that the NNGP is a well-defined spatial process providing legitimate finite-dimensional Gaussian densities with sparse precision matrices. We embed the NNGP as a sparsity-inducing prior within a rich hierarchical modeling framework and outline how computationally efficient Markov chain Monte Carlo (MCMC) algorithms can be executed without storing or decomposing large matrices. The floating point operations (flops) per iteration of this algorithm is linear in the number of spatial locations, thereby rendering substantial scalability. We illustrate the computational and inferential benefits of the NNGP over competing methods using simulation studies and also analyze forest biomass from a massive U.S. Forest Inventory dataset at a scale that precludes alternative dimension-reducing methods. Supplementary materials for this article are available online.

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Alan E. Gelfand

Sampling-Based Approaches to Calculating Marginal Densities

Hierarchical Modeling and Analysis for Spatial Data

Sampling-Based Approaches to Calculating Marginal Densities

Gaussian Predictive Process Models for Large Spatial Data Sets

Hierarchical Nearest-Neighbor Gaussian Process Models for Large Geostatistical Datasets

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