fitting spatial regression to large datasets using unilateral approximations

Giuseppe Arbia; Giuseppe Espa; Marco Bee; Flavio Santi

doi:10.1080/03610926.2017.1301476

fitting spatial regression to large datasets using unilateral approximations

Giuseppe Arbia
, Giuseppe Espa
, Marco Bee
, Flavio Santi^*

^*Autore corrispondente per questo lavoro

University of Trento

Risultato della ricerca: Contributo in rivista › Articolo › peer review

Abstract

Maximum likelihood estimation of spatial models typically requires a sizeable computational\r\ncapacity, even in relatively small samples and becomes unfeasible in very large datasets. The\r\nunilateral approximation approach to spatial models estimation (suggested in Besag, 1974) provides\r\na viable alternative to maximum likelihood estimation that reduces substantially computing\r\ntime and the storage required. Originally proposed for conditionally specified processes, in this 20\r\npaper we extend the method to simultaneous and to general bilateral spatial processes. We prove\r\nconsistency of the estimators and we study their finite-sample properties via Monte Carlo simulations.

Lingua originale	Inglese
pagine (da-a)	1-15
Numero di pagine	15
Rivista	Communications in Statistics - Theory and Methods
Volume	2017
Numero di pubblicazione	1
DOI	https://doi.org/10.1080/03610926.2017.1301476
Stato di pubblicazione	Pubblicato - 2017

All Science Journal Classification (ASJC) codes

Statistica e Probabilità

Keywords

Approximate Solution
Gaussian Process
Image Analysis
Spatial Regression
Very Large Dataset

Accesso al documento

10.1080/03610926.2017.1301476

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author = "Giuseppe Arbia and Giuseppe Espa and Marco Bee and Flavio Santi",

year = "2017",

doi = "10.1080/03610926.2017.1301476",

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AU - Arbia, Giuseppe

AU - Espa, Giuseppe

AU - Bee, Marco

AU - Santi, Flavio

PY - 2017

Y1 - 2017

N2 - Maximum likelihood estimation of spatial models typically requires a sizeable computational\r\ncapacity, even in relatively small samples and becomes unfeasible in very large datasets. The\r\nunilateral approximation approach to spatial models estimation (suggested in Besag, 1974) provides\r\na viable alternative to maximum likelihood estimation that reduces substantially computing\r\ntime and the storage required. Originally proposed for conditionally specified processes, in this 20\r\npaper we extend the method to simultaneous and to general bilateral spatial processes. We prove\r\nconsistency of the estimators and we study their finite-sample properties via Monte Carlo simulations.

AB - Maximum likelihood estimation of spatial models typically requires a sizeable computational\r\ncapacity, even in relatively small samples and becomes unfeasible in very large datasets. The\r\nunilateral approximation approach to spatial models estimation (suggested in Besag, 1974) provides\r\na viable alternative to maximum likelihood estimation that reduces substantially computing\r\ntime and the storage required. Originally proposed for conditionally specified processes, in this 20\r\npaper we extend the method to simultaneous and to general bilateral spatial processes. We prove\r\nconsistency of the estimators and we study their finite-sample properties via Monte Carlo simulations.

KW - Approximate Solution

KW - Gaussian Process

KW - Image Analysis

KW - Spatial Regression

KW - Very Large Dataset

KW - Approximate Solution

KW - Gaussian Process

KW - Image Analysis

KW - Spatial Regression

KW - Very Large Dataset

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fitting spatial regression to large datasets using unilateral approximations

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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