Fast Bayesian inference of block Nearest Neighbor Gaussian models for large data

Zaida C. Quiroz; Marcos O. Prates; Dipak K. Dey; H. åvard Rue

doi:10.1007/s11222-023-10227-1

Fast Bayesian inference of block Nearest Neighbor Gaussian models for large data

Zaida C. Quiroz
, Marcos O. Prates
, Dipak K. Dey
, H. åvard Rue

Sección de Matemáticas

Universidade Federal de Minas Gerais
University of Connecticut
King Abdullah University of Science and Technology

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

This paper presents the development of a spatial block-Nearest Neighbor Gaussian process (blockNNGP) for location-referenced large spatial data. The key idea behind this approach is to divide the spatial domain into several blocks which are dependent under some constraints. The cross-blocks capture the large-scale spatial dependence, while each block captures the small-scale spatial dependence. The resulting blockNNGP enjoys Markov properties reflected on its sparse precision matrix. It is embedded as a prior within the class of latent Gaussian models, thus fast Bayesian inference is obtained using the integrated nested Laplace approximation. The performance of the blockNNGP is illustrated on simulated examples, a comparison of our approach with other methods for analyzing large spatial data and applications with Gaussian and non-Gaussian real data.

Original language	English
Article number	54
Journal	Statistics and Computing
Volume	33
Issue number	2
DOIs	https://doi.org/10.1007/s11222-023-10227-1
State	Published - Apr 2023

Keywords

Geostatistics
INLA
Large datasets
NNGP
Parallel computing

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10.1007/s11222-023-10227-1

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title = "Fast Bayesian inference of block Nearest Neighbor Gaussian models for large data",

abstract = "This paper presents the development of a spatial block-Nearest Neighbor Gaussian process (blockNNGP) for location-referenced large spatial data. The key idea behind this approach is to divide the spatial domain into several blocks which are dependent under some constraints. The cross-blocks capture the large-scale spatial dependence, while each block captures the small-scale spatial dependence. The resulting blockNNGP enjoys Markov properties reflected on its sparse precision matrix. It is embedded as a prior within the class of latent Gaussian models, thus fast Bayesian inference is obtained using the integrated nested Laplace approximation. The performance of the blockNNGP is illustrated on simulated examples, a comparison of our approach with other methods for analyzing large spatial data and applications with Gaussian and non-Gaussian real data.",

keywords = "Geostatistics, INLA, Large datasets, NNGP, Parallel computing",

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note = "Publisher Copyright: {\textcopyright} 2023, The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.",

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T1 - Fast Bayesian inference of block Nearest Neighbor Gaussian models for large data

AU - Quiroz, Zaida C.

AU - Prates, Marcos O.

AU - Dey, Dipak K.

AU - Rue, H. åvard

PY - 2023/4

Y1 - 2023/4

N2 - This paper presents the development of a spatial block-Nearest Neighbor Gaussian process (blockNNGP) for location-referenced large spatial data. The key idea behind this approach is to divide the spatial domain into several blocks which are dependent under some constraints. The cross-blocks capture the large-scale spatial dependence, while each block captures the small-scale spatial dependence. The resulting blockNNGP enjoys Markov properties reflected on its sparse precision matrix. It is embedded as a prior within the class of latent Gaussian models, thus fast Bayesian inference is obtained using the integrated nested Laplace approximation. The performance of the blockNNGP is illustrated on simulated examples, a comparison of our approach with other methods for analyzing large spatial data and applications with Gaussian and non-Gaussian real data.

AB - This paper presents the development of a spatial block-Nearest Neighbor Gaussian process (blockNNGP) for location-referenced large spatial data. The key idea behind this approach is to divide the spatial domain into several blocks which are dependent under some constraints. The cross-blocks capture the large-scale spatial dependence, while each block captures the small-scale spatial dependence. The resulting blockNNGP enjoys Markov properties reflected on its sparse precision matrix. It is embedded as a prior within the class of latent Gaussian models, thus fast Bayesian inference is obtained using the integrated nested Laplace approximation. The performance of the blockNNGP is illustrated on simulated examples, a comparison of our approach with other methods for analyzing large spatial data and applications with Gaussian and non-Gaussian real data.

KW - Geostatistics

KW - INLA

KW - Large datasets

KW - NNGP

KW - Parallel computing

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DO - 10.1007/s11222-023-10227-1

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VL - 33

JO - Statistics and Computing

JF - Statistics and Computing

IS - 2

M1 - 54

ER -

Fast Bayesian inference of block Nearest Neighbor Gaussian models for large data

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