Sage Journals: Discover world-class research

Abstract

This paper aims to extend the Besag model, a widely used Bayesian spatial model in disease mapping, to a non-stationary spatial model for irregular lattice-type data. The goal is to improve the model’s ability to capture complex spatial dependence patterns and increase interpretability. The proposed model uses multiple precision parameters, accounting for different intensities of spatial dependence in different sub-regions. We derive a joint penalized complexity prior to the flexible local precision parameters to prevent overfitting and ensure contraction to the stationary model at a user-defined rate. The proposed methodology can be used as a basis for the development of various other non-stationary effects over other domains such as time. An accompanying R package fbesag equips the reader with the necessary tools for immediate use and application. We illustrate the novelty of the proposal by modeling the risk of dengue in Brazil, where the stationary spatial assumption fails and interesting risk profiles are estimated when accounting for spatial non-stationary. Additionally, we model different causes of death in Brazil, where we use the new model to investigate the spatial stationarity of these causes.

Keywords

Non-stationary spatial model disease mapping besag model Integrated Nested Laplace Approximations penalizing complexity prior

Get full access to this article

View all access options for this article.

References

Besag

. Spatial interaction and the statistical analysis of lattice systems. J R Stat Soc: Ser B (Methodological) 1974; 36: 192–225.

Duncan

White

Mengersen

. Spatial smoothing in Bayesian models: A comparison of weights matrix specifications and their impact on inference. Int J Health Geogr 2017; 16: 1–16.

MacNab

. Bayesian disease mapping: Past, present, and future. Spat Stat 2022; 50: 100593.

Besag

York

Mollié

. Bayesian image restoration, with two applications in spatial statistics. Ann Inst Stat Math 1991; 43: 1–20.

Leroux

Lei

Breslow

. Estimation of disease rates in small areas: A new mixed model for spatial dependence. In Statistical models in epidemiology, the environment, and clinical trials. Springer, pp. 179–191.

Dean

Ugarte

Militino

. Detecting interaction between random region and fixed age effects in disease mapping. Biometrics 2001; 57: 197–202.

Riebler

Sørbye

Simpson

et al. An intuitive Bayesian spatial model for disease mapping that accounts for scaling. Stat Methods Med Res 2016; 25: 1145–1165.

Sørbye

Rue

. Scaling intrinsic Gaussian Markov random field priors in spatial modelling. Spat Stat 2014; 8: 39–51.

MacNab

Gustafson

. Regression B-spline smoothing in Bayesian disease mapping: With an application to patient safety surveillance. Stat Med 2007; 26: 4455–4474.

10.

Goicoa

Ugarte

Etxeberria

et al. Comparing car and p-spline models in spatial disease mapping. Environ Ecol Stat 2012; 19: 573–599.

11.

Orozco-Acosta

Adin

Ugarte

. Scalable Bayesian modelling for smoothing disease risks in large spatial data sets using INLA. Spat Stat 2021; 41: 100496.

12.

Bezdek

. Pattern recognition with fuzzy objective function algorithms. In Advanced Applications in Pattern Recognition.

13.

Ferraro

Giordani

Serafini

. fclust: An r package for fuzzy clustering. R J 2019; 11: 198.

14.

Karypis

. Metis, a software package for partitioning unstructured graphs, partitioning meshes, and computing fill-reducing orderings of sparse matrices version 4.0. http://glaros dtc umn edu/gkhome/metis/metis/download 1997.

15.

Karypis

Kumar

. A fast and high quality multilevel scheme for partitioning irregular graphs. SIAM J Sci Comput 1998; 20: 359–392.

16.

Karypis

Kumar

. Multilevel k-way partitioning scheme for irregular graphs. J Parallel Distributed Comput 1998; 48: 96–129.

17.

Bhatt

Gething

Brady

et al. The global distribution and burden of dengue. Nature 2013; 496: 504–507.

18.

Lowe

Lee

O’Reilly

et al. Combined effects of hydrometeorological hazards and urbanization on dengue risk in brazil: A spatiotemporal modelling study. Lancet Planet Health 2021; 5: e209–e219.

19.

Simpson

Rue

Martins

et al. Penalising model component complexity: A principled, practical approach to constructing priors. Stat Sci 2014; 32: 1–28.

20.

Rue

Martino

Chopin

. Approximate Bayesian inference for latent Gaussian models using integrated nested laplace approximations (with discussion). JRSSB 2009; 71: 319–392.

21.

Martins

Simpson

Lindgren

et al. Bayesian computing with INLA: New features. Comput Stat Data Anal 2013; 67: 68–83.

22.

Van Niekerk

Krainski

Rustand

et al. A new avenue for Bayesian inference with INLA. Comput Stat Data Anal 2023;: .

23.

Liu

Rue

. Leave-group-out cross-validation for latent gaussian models. arXiv preprint arXiv:221004482 2022;.

24.

Fattah

Rue

. Approximate Bayesian inference for the interaction types 1, 2, 3 and 4 with application in disease mapping. arXiv preprint arXiv:220609287 2022.

25.

Ahmad

Dey

. A k-mean clustering algorithm for mixed numeric and categorical data. Data Knowl Eng 2007; 63: 503–527.

26.

Kanungo

Mount

Netanyahu

et al. An efficient k-means clustering algorithm: Analysis and implementation. IEEE Trans Pattern Anal Mach Intell 2002; 24: 881–892.

27.

Likas

Vlassis

Verbeek

. The global k-means clustering algorithm. Pattern Recognit 2003; 36: 451–461.

28.

Winkler

Klawonn

Kruse

. Fuzzy clustering with polynomial fuzzifier function in connection with m-estimators. Appl Comput Math 2011; 10: 146–163.

29.

Zhou

Chen

et al. Fuzzy clustering with the entropy of attribute weights. Neurocomputing 2016; 198: 125–134.

30.

Kullback

Leibler

. On information and sufficiency. Ann Math Stat 1951; 22: 79–86.

31.

Fuglstad

Simpson

Lindgren

et al. Constructing priors that penalize the complexity of gaussian random fields. J Am Stat Assoc 2019; 114: 445–452.

Non-stationary Bayesian spatial model for disease mapping based on sub-regions

Abstract

Keywords

Get full access to this article

References