Your search keyword '"Håvard Rue"' showing total 160 results

1. Spatio‐temporal occupancy models with INLA

Author

Jafet Belmont, Sara Martino, Janine Illian, and Håvard Rue

Subjects

Bayesian inference, detectability, INLA, species distributions, Ecology, QH540-549.5, Evolution, QH359-425

Abstract

Abstract Modern methods for quantifying, predicting and mapping species distributions have played a crucial part in biodiversity conservation. Occupancy models have become a popular choice for analysing species occurrence data due to their ability to separate out the observational error induced by imperfect detection of a species, and the sources of bias affecting the occupancy process. However, the spatial and temporal variation in occupancy that is not accounted for by environmental covariates is often ignored or modelled through simple spatial structures as the computational costs of fitting explicit spatio‐temporal models is too high. In this work, we demonstrate how Integrated Nested Laplace Approximation (INLA) may be used to fit complex spatio‐temporal occupancy models and how the R‐INLA package can provide a user‐friendly interface to make such complex models available to users. We show how occupancy models, provided some simplification on the detection process is assumed, can be framed as latent Gaussian models and, as such, benefit from the powerful INLA framework. A large selection of complex modelling features, and random effect models, including spatio‐temporal models, have already been implemented in R‐INLA. These also become available for occupancy models, providing the user with an efficient, reliable and flexible toolbox. We illustrate how INLA provides a flexible and computationally efficient framework for developing and fitting complex occupancy models using two complex case studies. Through these, we show how different spatio‐temporal models that include spatial‐varying trends, smooth terms and spatio‐temporal random effects can be fitted to aggregated detection/non‐detection data. At the cost of limiting the complexity of the detection model structure, INLA can incorporate a range of rather complex structures in the ecological process of interest and hence, extend the functionality of occupancy models. The limitations of occupancy models in terms of scalability for large spatio‐temporal data sets remain a challenge and an active area of research. INLA‐based occupancy models provide an alternative inferential and computational framework to fit complex spatio‐temporal occupancy models. The need for new and more flexible computationally efficient approaches to fit such models makes INLA an attractive option for addressing complex ecological problems, and a promising area of research.

Published

2024

2. Joint quantile disease mapping with application to malaria and G6PD deficiency

Author

Hanan Alahmadi, Janet van Niekerk, Tullia Padellini, and Håvard Rue

Subjects

Bayesian analysis, disease mapping, integrated nested Laplace approximation, joint quantile regression, Science

Abstract

Statistical analysis based on quantile methods is more comprehensive, flexible and less sensitive to outliers when compared to mean methods. Joint disease mapping is useful for inferring correlation between different diseases. Most studies investigate this link through multiple correlated mean regressions. We propose a joint quantile regression framework for multiple diseases where different quantile levels can be considered. We are motivated by the theorized link between the presence of malaria and the gene deficiency G6PD, where medical scientists have anecdotally discovered a possible link between high levels of G6PD and lower than expected levels of malaria initially pointing towards the occurrence of G6PD inhibiting the occurrence of malaria. Thus, the need for flexible joint quantile regression in a disease mapping framework arises. Our model can be used for linear and nonlinear effects of covariates by stochastic splines since we define it as a latent Gaussian model. We perform Bayesian inference using the R integrated nested Laplace approximation, suitable even for large datasets. Finally, we illustrate the model’s applicability by considering data from 21 countries, although better data are needed to prove a significant relationship. The proposed methodology offers a framework for future studies of interrelated disease phenomena.

Published

2024

3. New Frontiers in Bayesian Modeling Using the INLA Package in R

Author

Janet Van Niekerk, Haakon Bakka, Håvard Rue, and Olaf Schenk

Subjects

inla, joint model, non-separable, spatial, temporal, Statistics, HA1-4737

Abstract

The INLA package provides a tool for computationally efficient Bayesian modeling and inference for various widely used models, more formally the class of latent Gaussian models. It is a non-sampling based framework which provides approximate results for Bayesian inference, using sparse matrices. The swift uptake of this framework for Bayesian modeling is rooted in the computational efficiency of the approach and catalyzed by the demand presented by the big data era. In this paper, we present new developments within the INLA package with the aim to provide a computationally efficient mechanism for the Bayesian inference of relevant challenging situations.

Published

2021

4. Estimating Animal Abundance with N-Mixture Models Using the R-INLA Package for R

Author

Timothy D. Meehan, Nicole L. Michel, and Håvard Rue

Subjects

abundance, detection, jags, $n$-mixture model, r-inla, unmarked, wildlife, Statistics, HA1-4737

Abstract

Successful management of wildlife populations requires accurate estimates of abundance. Abundance estimates can be confounded by imperfect detection during wildlife surveys. N-mixture models enable quantification of detection probability and, under appropriate conditions, produce abundance estimates that are less biased. Here, we demonstrate how to use the R-INLA package for R to analyze N-mixture models, and compare performance of R-INLA to two other common approaches: JAGS (via the runjags package for R), which uses Markov chain Monte Carlo and allows Bayesian inference, and the unmarked package for R, which uses maximum likelihood and allows frequentist inference. We show that R-INLA is an attractive option for analyzing N-mixture models when (i) fast computing times are necessary (R-INLA is 10 times faster than unmarked and 500 times faster than JAGS), (ii) familiar model syntax and data format (relative to other R packages) is desired, (iii) survey-level covariates of detection are not essential, and (iv) Bayesian inference is preferred.

Published

2020

5. Combined effects of hydrometeorological hazards and urbanisation on dengue risk in Brazil: a spatiotemporal modelling study

Author

Rachel Lowe, PhD, Sophie A Lee, MSc, Kathleen M O'Reilly, PhD, Oliver J Brady, DPhil, Leonardo Bastos, PhD, Gabriel Carrasco-Escobar, MSc, Rafael de Castro Catão, PhD, Felipe J Colón-González, PhD, Christovam Barcellos, PhD, Marilia Sá Carvalho, PhD, Marta Blangiardo, ProfPhD, Håvard Rue, ProfPhD, and Antonio Gasparrini, ProfPhD

Subjects

Environmental sciences, GE1-350

Abstract

Summary: Background: Temperature and rainfall patterns are known to influence seasonal patterns of dengue transmission. However, the effect of severe drought and extremely wet conditions on the timing and intensity of dengue epidemics is poorly understood. In this study, we aimed to quantify the non-linear and delayed effects of extreme hydrometeorological hazards on dengue risk by level of urbanisation in Brazil using a spatiotemporal model. Methods: We combined distributed lag non-linear models with a spatiotemporal Bayesian hierarchical model framework to determine the exposure-lag-response association between the relative risk (RR) of dengue and a drought severity index. We fit the model to monthly dengue case data for the 558 microregions of Brazil between January, 2001, and January, 2019, accounting for unobserved confounding factors, spatial autocorrelation, seasonality, and interannual variability. We assessed the variation in RR by level of urbanisation through an interaction between the drought severity index and urbanisation. We also assessed the effect of hydrometeorological hazards on dengue risk in areas with a high frequency of water supply shortages. Findings: The dataset included 12 895 293 dengue cases reported between 2001 and 2019 in Brazil. Overall, the risk of dengue increased between 0–3 months after extremely wet conditions (maximum RR at 1 month lag 1·56 [95% CI 1·41–1·73]) and 3–5 months after drought conditions (maximum RR at 4 months lag 1·43 [1·22–1·67]). Including a linear interaction between the drought severity index and level of urbanisation improved the model fit and showed the risk of dengue was higher in more rural areas than highly urbanised areas during extremely wet conditions (maximum RR 1·77 [1·32–2·37] at 0 months lag vs maximum RR 1·58 [1·39–1·81] at 2 months lag), but higher in highly urbanised areas than rural areas after extreme drought (maximum RR 1·60 [1·33–1·92] vs 1·15 [1·08–1·22], both at 4 months lag). We also found the dengue risk following extreme drought was higher in areas that had a higher frequency of water supply shortages. Interpretation: Wet conditions and extreme drought can increase the risk of dengue with different delays. The risk associated with extremely wet conditions was higher in more rural areas and the risk associated with extreme drought was exacerbated in highly urbanised areas, which have water shortages and intermittent water supply during droughts. These findings have implications for targeting mosquito control activities in poorly serviced urban areas, not only during the wet and warm season, but also during drought periods. Funding: Royal Society, Medical Research Council, Wellcome Trust, National Institutes of Health, Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro, and Conselho Nacional de Desenvolvimento Científico e Tecnológico. Translation: For the Portuguese translation of the abstract see Supplementary Materials section.

Published

2021

6. Skewed Probit Regression

Author

Janet van Niekerk and Håvard Rue

Subjects

skew symmetric, probit, binary regression, penalizing complexity, INLA, Statistics, HA1-4737, Probabilities. Mathematical statistics, QA273-280

Abstract

Skewed probit regression is but one example of a statistical model that generalizes a simpler model, like probit regression. All skew-symmetric distributions and link functions arise from symmetric distributions by incorporating a skewness parameter through some skewing mechanism. In this work we address some fundamental issues in skewed probit regression, and more genreally skewsymmetric distributions or skew-symmetric link functions. We address the issue of identifiability of the skewed probit model parameters by reformulating the intercept from first principles. A new standardization of the skew link function is given to provide and anchored interpretation of the inference. Possible skewness parameters are investigated and the penalizing complexity priors of these are derived. This prior is invariant under reparameterization of the skewness parameter and quantifies the contraction of the skewed probit model to the probit model. The proposed results are available in the R-INLA package and we illustrate the use and effects of this work using simulated data, and well-known datasets using the link as well as the likelihood.

Published

2021

7. Estimating Spatial Econometrics Models with Integrated Nested Laplace Approximation

Author

Virgilio Gómez-Rubio, Roger S. Bivand, and Håvard Rue

Subjects

Bayesian inference, INLA, spatial econometrics, spatial statistics, Mathematics, QA1-939

Abstract

The integrated nested Laplace approximation (INLA) provides a fast and effective method for marginal inference in Bayesian hierarchical models. This methodology has been implemented in the R-INLA package which permits INLA to be used from within R statistical software. Although INLA is implemented as a general methodology, its use in practice is limited to the models implemented in the R-INLA package. Spatial autoregressive models are widely used in spatial econometrics but have until now been lacking from the R-INLA package. In this paper, we describe the implementation and application of a new class of latent models in INLA made available through R-INLA. This new latent class implements a standard spatial lag model. The implementation of this latent model in R-INLA also means that all the other features of INLA can be used for model fitting, model selection and inference in spatial econometrics, as will be shown in this paper. Finally, we will illustrate the use of this new latent model and its applications with two data sets based on Gaussian and binary outcomes.

Published

2021

8. Bayesian Model Averaging with the Integrated Nested Laplace Approximation

Author

Virgilio Gómez-Rubio, Roger S. Bivand, and Håvard Rue

Subjects

Bayesian model averaging, INLA, spatial econometrics, Economics as a science, HB71-74

Abstract

The integrated nested Laplace approximation (INLA) for Bayesian inference is an efficient approach to estimate the posterior marginal distributions of the parameters and latent effects of Bayesian hierarchical models that can be expressed as latent Gaussian Markov random fields (GMRF). The representation as a GMRF allows the associated software R-INLA to estimate the posterior marginals in a fraction of the time as typical Markov chain Monte Carlo algorithms. INLA can be extended by means of Bayesian model averaging (BMA) to increase the number of models that it can fit to conditional latent GMRF. In this paper, we review the use of BMA with INLA and propose a new example on spatial econometrics models.

Published

2020

9. Bayesian Spatial Modelling with R-INLA

Author

Finn Lindgren and Håvard Rue

Subjects

Statistics, HA1-4737

Abstract

The principles behind the interface to continuous domain spatial models in the R- INLA software package for R are described. The integrated nested Laplace approximation (INLA) approach proposed by Rue, Martino, and Chopin (2009) is a computationally effective alternative to MCMC for Bayesian inference. INLA is designed for latent Gaussian models, a very wide and flexible class of models ranging from (generalized) linear mixed to spatial and spatio-temporal models. Combined with the stochastic partial differential equation approach (SPDE, Lindgren, Rue, and Lindstrm 2011), one can accommodate all kinds of geographically referenced data, including areal and geostatistical ones, as well as spatial point process data. The implementation interface covers stationary spatial mod- els, non-stationary spatial models, and also spatio-temporal models, and is applicable in epidemiology, ecology, environmental risk assessment, as well as general geostatistics.

Published

2015

10. Spatial Data Analysis with R-INLA with Some Extensions

Author

Roger Bivand, Virgilio Gómez-Rubio, and Håvard Rue

Subjects

Statistics, HA1-4737

Abstract

The integrated nested Laplace approximation (INLA) provides an interesting way of approximating the posterior marginals of a wide range of Bayesian hierarchical models. This approximation is based on conducting a Laplace approximation of certain functions and numerical integration is extensively used to integrate some of the models parameters out. The R-INLA package offers an interface to INLA, providing a suitable framework for data analysis. Although the INLA methodology can deal with a large number of models, only the most relevant have been implemented within R-INLA. However, many other important models are not available for R-INLA yet. In this paper we show how to fit a number of spatial models with R-INLA, including its interaction with other R packages for data analysis. Secondly, we describe a novel method to extend the number of latent models available for the model parameters. Our approach is based on conditioning on one or several model parameters and fit these conditioned models with R-INLA. Then these models are combined using Bayesian model averaging to provide the final approximations to the posterior marginals of the model. Finally, we show some examples of the application of this technique in spatial statistics. It is worth noting that our approach can be extended to a number of other fields, and not only spatial statistics.

Published

2015

11. Bayesian 2D Deconvolution: A Model for Diffuse Ultrasound Scattering

Author

Oddvar Husby, Torgrim Lie, Thomas Langø, Jørn Hokland, and Håvard Rue

Subjects

Medical ultrasound, restoration, Markov random fields, diffuse scattering, Electronic computers. Computer science, QA75.5-76.95

Abstract

Observed medical ultrasound images are degraded representations of the true acoustic tissue reflectance. The degradation is due to blur and speckle, and significantly reduces the diagnostic value of the images. In order to remove both blur and speckle we have developed a new statistical model for diffuse scattering in 2D ultrasound radio-frequency images, incorporating both spatial smoothness constraints and a physical model for diffuse scattering. The modeling approach is Bayesian in nature, and we use Markov chain Monte Carlo methods to obtain the restorations. The results from restorations of some real and simulated radio-frequency ultrasound images are presented and compared with results produced by Wiener filtering.

Published

2001

12. Variance partitioning in spatio-temporal disease mapping models

Author

Maria Franco-Villoria, Massimo Ventrucci, and Håvard Rue

Subjects

FOS: Computer and information sciences, Statistics and Probability, Models, Statistical, spatio-temporal smoothing, Epidemiology, Intrinsic Gaussian Markov random fields, Bayes Theorem, Kronecker product Gaussian Markov random fields, Methodology (stat.ME), intrinsic conditional autoregressive, penalized complexity prior, Health Information Management, Statistics - Methodology

Abstract

Bayesian disease mapping, yet if undeniably useful to describe variation in risk over time and space, comes with the hurdle of prior elicitation on hard-to-interpret random effect precision parameters. We introduce a reparametrized version of the popular spatio-temporal interaction models, based on Kronecker product intrinsic Gaussian Markov random fields, that we name the variance partitioning model. The variance partitioning model includes a mixing parameter that balances the contribution of the main and interaction effects to the total (generalized) variance and enhances interpretability. The use of a penalized complexity prior on the mixing parameter aids in coding prior information in an intuitive way. We illustrate the advantages of the variance partitioning model using two case studies.

Published

2022

13. Bayesian estimation of two‐part joint models for a longitudinal semicontinuous biomarker and a terminal event with INLA: Interests for cancer clinical trial evaluation

Author

Denis Rustand, Janet van Niekerk, Håvard Rue, Christophe Tournigand, Virginie Rondeau, and Laurent Briollais

Subjects

Statistics and Probability, General Medicine, Statistics, Probability and Uncertainty

Published

2023

14. Sex Differences in Survival Chances Among Children, Adolescents, and Youth Ages 0–24: A Systematic Assessment of National, Regional, and Global Trends from 1990 to 2021

Author

Fengqing Chao, Bruno Masquelier, Danzhen You, Lucia Hug, Yang Liu, David Sharrow, Håvard Rue, Hernando Ombao, and Leontine Alkema

Published

2023

15. Parallelized integrated nested Laplace approximations for fast Bayesian inference

Author

Lisa Gaedke-Merzhäuser, Janet van Niekerk, Olaf Schenk, and Håvard Rue

Subjects

FOS: Computer and information sciences, Statistics and Probability, Computer Science - Distributed, Parallel, and Cluster Computing, Computational Theory and Mathematics, Distributed, Parallel, and Cluster Computing (cs.DC), Statistics, Probability and Uncertainty, Statistics - Computation, Computation (stat.CO), Theoretical Computer Science

Abstract

There is a growing demand for performing larger-scale Bayesian inference tasks, arising from greater data availability and higher-dimensional model parameter spaces. In this work we present parallelization strategies for the methodology of integrated nested Laplace approximations (INLA), a popular framework for performing approximate Bayesian inference on the class of Latent Gaussian models. Our approach makes use of nested OpenMP parallelism, a parallel line search procedure using robust regression in INLA's optimization phase and the state-of-the-art sparse linear solver PARDISO. We leverage mutually independent function evaluations in the algorithm as well as advanced sparse linear algebra techniques. This way we can flexibly utilize the power of today's multi-core architectures. We demonstrate the performance of our new parallelization scheme on a number of different real-world applications. The introduction of parallelism leads to speedups of a factor 10 and more for all larger models. Our work is already integrated in the current version of the open-source R-INLA package, making its improved performance conveniently available to all users., 18 pages, 7 figures

Published

2022

16. Bandwidth of the Ultrasound Doppler Signal with Applications in Blood/Tissue Segmentation in the Left Ventricle.

Author

Sigve Hovda, Håvard Rue, and Bjørn Olstad

Published

2007

17. New Doppler-Based Imaging Method in Echocardiography with Applications in Blood/Tissue Segmentation.

Author

Sigve Hovda, Håvard Rue, and Bjørn Olstad

Published

2007

18. Practical strategies for generalized extreme value‐based regression models for extremes

Author

Daniela Castro‐Camilo, Raphaël Huser, and Håvard Rue

Subjects

Statistics and Probability, Ecological Modeling

Published

2022

19. A new avenue for Bayesian inference with INLA

Author

Janet Van Niekerk, Elias Krainski, Denis Rustand, and Håvard Rue

Subjects

Methodology (stat.ME), FOS: Computer and information sciences, Statistics and Probability, Computational Mathematics, Computational Theory and Mathematics, Applied Mathematics, Statistics - Methodology

Abstract

Integrated Nested Laplace Approximations (INLA) has been a successful approximate Bayesian inference framework since its proposal by Rue et al. (2009). The increased computational efficiency and accuracy when compared with sampling-based methods for Bayesian inference like MCMC methods, are some contributors to its success. Ongoing research in the INLA methodology and implementation thereof in the R package R-INLA, ensures continued relevance for practitioners and improved performance and applicability of INLA. The era of big data and some recent research developments, presents an opportunity to reformulate some aspects of the classic INLA formulation, to achieve even faster inference, improved numerical stability and scalability. The improvement is especially noticeable for data-rich models. We demonstrate the efficiency gains with various examples of data-rich models, like Cox's proportional hazards model, an item-response theory model, a spatial model including prediction, and a 3-dimensional model for fMRI data.

Published

2023

20. Use of the INLA Approach for the Analysis of Interval-Censored Data

Author

Janet van Niekerk and Håvard Rue

Published

2022

21. Controlling the flexibility of non-Gaussian processes through shrinkage priors

Author

Rafael Cabral, David Bolin, and Håvard Rue

Subjects

Statistics and Probability, Methodology (stat.ME), FOS: Computer and information sciences, 62F15, 62M20 (Primary), 62M40 (Secondary), Applied Mathematics, Statistics - Methodology

Abstract

The normal inverse Gaussian (NIG) and generalized asymmetric Laplace (GAL) distributions can be seen as skewed and semi-heavy-tailed extensions of the Gaussian distribution. Models driven by these more flexible noise distributions are then regarded as flexible extensions of simpler Gaussian models. Inferential procedures tend to overestimate the degree of non-Gaussianity in the data and therefore we propose controlling the flexibility of these non-Gaussian models by adding sensible priors in the inferential framework that contract the model towards Gaussianity. In our venture to derive sensible priors, we also propose a new intuitive parameterization of the non-Gaussian models and discuss how to implement them efficiently in $Stan$. The methods are derived for a generic class of non-Gaussian models that include spatial Mat\'ern fields, autoregressive models for time series, and simultaneous autoregressive models for aerial data. The results are illustrated with a simulation study and geostatistics application, where priors that penalize model complexity were shown to lead to more robust estimation and give preference to the Gaussian model, while at the same time allowing for non-Gaussianity if there is sufficient evidence in the data., Comment: 34 pages, 12 figures; Added new section about Stan implementation and a cross-validation study in the application section, removed unecessary details

Published

2022

22. Quantification of Empirical Determinacy: The Impact of Likelihood Weighting on Posterior Location and Spread in Bayesian Meta-Analysis Estimated with JAGS and INLA

Author

Sona, Hunanyan, primary, Håvard, Rue, additional, Martyn, Plummer, additional, and Małgorzata, Roos, additional

Published

2022

23. A Spliced Gamma-Generalized Pareto Model for Short-Term Extreme Wind Speed Probabilistic Forecasting

Author

Håvard Rue, Daniela Castro-Camilo, and Raphaël Huser

Subjects

0106 biological sciences, Statistics and Probability, Mathematical optimization, Computer science, Astrophysics::High Energy Astrophysical Phenomena, 010603 evolutionary biology, 01 natural sciences, Wind speed, 010104 statistics & probability, Generalized Pareto distribution, 0101 mathematics, Extreme value theory, Physics::Atmospheric and Oceanic Physics, General Environmental Science, Wind power, business.industry, Applied Mathematics, Probabilistic logic, Pareto principle, Agricultural and Biological Sciences (miscellaneous), Renewable energy, Physics::Space Physics, Probabilistic forecasting, Statistics, Probability and Uncertainty, General Agricultural and Biological Sciences, business

Abstract

Renewable sources of energy such as wind power have become a sustainable alternative to fossil fuel-based energy. However, the uncertainty and fluctuation of the wind speed derived from its intermittent nature bring a great threat to the wind power production stability, and to the wind turbines themselves. Lately, much work has been done on developing models to forecast average wind speed values, yet surprisingly little has focused on proposing models to accurately forecast extreme wind speeds, which can damage the turbines. In this work, we develop a flexible spliced Gamma-Generalized Pareto model to forecast extreme and non-extreme wind speeds simultaneously. Our model belongs to the class of latent Gaussian models, for which inference is conveniently performed based on the integrated nested Laplace approximation method. Considering a flexible additive regression structure, we propose two models for the latent linear predictor to capture the spatio-temporal dynamics of wind speeds. Our models are fast to fit and can describe both the bulk and the tail of the wind speed distribution while producing short-term extreme and non-extreme wind speed probabilistic forecasts. Supplementary materials accompanying this paper appear online.

Published

2019

24. A Hierarchical Spatiotemporal Statistical Model Motivated by Glaciology

Author

Finnur Pálsson, Guðfinna Aðalgeirsdóttir, Birgir Hrafnkelsson, Giri Gopalan, Håvard Rue, Christopher K. Wikle, and Alexander H. Jarosch

Subjects

0106 biological sciences, Statistics and Probability, Emulation, Computer science, Applied Mathematics, Physical system, Inference, Statistical model, Solver, 010603 evolutionary biology, 01 natural sciences, Agricultural and Biological Sciences (miscellaneous), 010104 statistics & probability, Linear algebra, 0101 mathematics, Statistics, Probability and Uncertainty, Scenario testing, Uncertainty quantification, General Agricultural and Biological Sciences, Algorithm, General Environmental Science

Abstract

In this paper, we extend and analyze a Bayesian hierarchical spatiotemporal model for physical systems. A novelty is to model the discrepancy between the output of a computer simulator for a physical process and the actual process values with a multivariate random walk. For computational efficiency, linear algebra for bandwidth limited matrices is utilized, and first-order emulator inference allows for the fast emulation of a numerical partial differential equation (PDE) solver. A test scenario from a physical system motivated by glaciology is used to examine the speed and accuracy of the computational methods used, in addition to the viability of modeling assumptions. We conclude by discussing how the model and associated methodology can be applied in other physical contexts besides glaciology.

Published

2019

25. Tracking of multiple quantiles in dynamically varying data streams

Author

Anis Yazidi, Hugo Lewi Hammer, and Håvard Rue

Subjects

Data stream, ComputingMethodologies_SIMULATIONANDMODELING, Data stream mining, Computer science, Property (programming), Sample (statistics), Tracking (particle physics), Quantile tracking, Multiple quantiles, Monotone polygon, Artificial Intelligence, Pattern recognition (psychology), Dynamic environments, Computer Vision and Pattern Recognition, Incremental algorithms, Algorithm, Quantile

Abstract

In this paper we consider the problem of tracking multiple quantiles of dynamicallyvarying data stream distributions. The method is based on making incremental updates ofthe quantile estimates every time a new sample is received. The method is memory andcomputationally efficient since it only stores one value for each quantile estimate and onlyperforms one operation per quantile estimate when a new sample is received from the datastream. The estimates are realistic in the sense that the monotone property of quantiles issatisfied in every iteration. Experiments show that the method efficiently tracks multiplequantiles and outperforms state of the art methods.

Published

2019

26. Modelling sub-daily precipitation extremes with the blended generalised extreme value distribution

Author

Silius M. Vandeskog, Sara Martino, Daniela Castro-Camilo, and Håvard Rue

Subjects

FOS: Computer and information sciences, Statistics and Probability, Applied Mathematics, Applications (stat.AP), Statistics, Probability and Uncertainty, General Agricultural and Biological Sciences, Agricultural and Biological Sciences (miscellaneous), Statistics - Applications, General Environmental Science

Abstract

A new method is proposed for modelling the yearly maxima of sub-daily precipitation, with the aim of producing spatial maps of return level estimates. Yearly precipitation maxima are modelled using a Bayesian hierarchical model with a latent Gaussian field, with the blended generalised extreme value (bGEV) distribution used as a substitute for the more standard generalised extreme value (GEV) distribution. Inference is made less wasteful with a novel two-step procedure that performs separate modelling of the scale parameter of the bGEV distribution using peaks over threshold data. Fast inference is performed using integrated nested Laplace approximations (INLA) together with the stochastic partial differential equation approach, both implemented in . Heuristics for improving the numerical stability of with the GEV and bGEV distributions are also presented. The model is fitted to yearly maxima of sub-daily precipitation from the south of Norway and is able to quickly produce high-resolution return level maps with uncertainty. The proposed two-step procedure provides an improved model fit over standard inference techniques when modelling the yearly maxima of sub-daily precipitation with the bGEV distribution. Supplementary materials accompanying this paper appear on-line.

Published

2021

27. Importance Sampling with the Integrated Nested Laplace Approximation

Author

Martin Outzen Berild, Sara Martino, Virgilio Gómez-Rubio, and Håvard Rue

Subjects

Statistics and Probability, Methodology (stat.ME), FOS: Computer and information sciences, Statistics::Applications, Discrete Mathematics and Combinatorics, Statistics, Probability and Uncertainty, Statistics - Computation, Computation (stat.CO), Statistics - Methodology, Statistics::Computation

Abstract

The integrated nested Laplace approximation (INLA) is a deterministic approach to Bayesian inference on latent Gaussian models (LGMs) and focuses on fast and accurate approximation of posterior marginals for the parameters in the models. Recently, methods have been developed to extend this class of models to those that can be expressed as conditional LGMs by fixing some of the parameters in the models to descriptive values. These methods differ in the manner descriptive values are chosen. This article proposes to combine importance sampling with INLA (IS-INLA), and extends this approach with the more robust adaptive multiple importance sampling algorithm combined with INLA (AMIS-INLA). This article gives a comparison between these approaches and existing methods on a series of applications with simulated and observed datasets and evaluates their performance based on accuracy, efficiency, and robustness. The approaches are validated by exact posteriors in a simple bivariate linear model; then, they are applied to a Bayesian lasso model, a Poisson mixture, a zero-inflated Poisson model and a spatial autoregressive combined model. The applications show that the AMIS-INLA approach, in general, outperforms the other methods compared, but the IS-INLA algorithm could be considered for faster inference when good proposals are available. Supplementary materials for this article are available online.

Published

2021

28. The SPDE approach for Gaussian and non-Gaussian fields: 10 years and still running

Author

Finn Lindgren, David Bolin, and Håvard Rue

Subjects

Statistics and Probability, Methodology (stat.ME), FOS: Computer and information sciences, Management, Monitoring, Policy and Law, Computers in Earth Sciences, 60G60 (Primary), 60G60, 62M40, 62-08 (Secondary), Statistics - Methodology

Abstract

Gaussian processes and random fields have a long history, covering multiple approaches to representing spatial and spatio-temporal dependence structures, such as covariance functions, spectral representations, reproducing kernel Hilbert spaces, and graph based models. This article describes how the stochastic partial differential equation approach to generalising Mat\'ern covariance models via Hilbert space projections connects with several of these approaches, with each connection being useful in different situations. In addition to an overview of the main ideas, some important extensions, theory, applications, and other recent developments are discussed. The methods include both Markovian and non-Markovian models, non-Gaussian random fields, non-stationary fields and space-time fields on arbitrary manifolds, and practical computational considerations., Comment: 33 pages, 1 figure

Published

2021

29. Statistical estimation of global surface temperature response to forcing under the assumption of temporal scaling

Author

Hege-Beate Fredriksen, Eirik Myrvoll-Nilsen, Håvard Rue, Sigrunn Holbek Sørbye, and Martin Rypdal

Subjects

Surface (mathematics), lcsh:Dynamic and structural geology, 010504 meteorology & atmospheric sciences, 01 natural sciences, 010104 statistics & probability, lcsh:QE500-639.5, media_common.cataloged_instance, 0101 mathematics, European union, lcsh:Science, Scaling, 0105 earth and related environmental sciences, media_common, Estimation, Forcing (recursion theory), Horizon (archaeology), lcsh:QE1-996.5, VDP::Matematikk og Naturvitenskap: 400::Matematikk: 410, VDP::Mathematics and natural science: 400::Mathematics: 410, lcsh:Geology, 13. Climate action, Climatology, General Earth and Planetary Sciences, lcsh:Q, Temperature response, Geology

Abstract

Reliable quantification of the global mean surface temperature (GMST) response to radiative forcing is essential for assessing the risk of dangerous anthropogenic climate change. We present the statistical foundations for an observation-based approach using a stochastic linear response model that is consistent with the long-range temporal dependence observed in global temperature variability. We have incorporated the model in a latent Gaussian modeling framework, which allows for the use of integrated nested Laplace approximations (INLAs) to perform full Bayesian analysis. As examples of applications, we estimate the GMST response to forcing from historical data and compute temperature trajectories under the Representative Concentration Pathways (RCPs) for future greenhouse gas forcing. For historic runs in the Model Intercomparison Project Phase 5 (CMIP5) ensemble, we estimate response functions and demonstrate that one can infer the transient climate response (TCR) from the instrumental temperature record. We illustrate the effect of long-range dependence by comparing the results with those obtained from one-box and two-box energy balance models. The software developed to perform the given analyses is publicly available as the R package INLA.climate.

Published

2020

30. A principled distance-based prior for the shape of the Weibull model

Author

Haakon Bakka, Håvard Rue, and J. van Niekerk

Subjects

Statistics and Probability, FOS: Computer and information sciences, 010102 general mathematics, 01 natural sciences, Shape parameter, Methodology (stat.ME), 010104 statistics & probability, Component (UML), 0101 mathematics, Statistics, Probability and Uncertainty, Algorithm, Statistics - Methodology, Weibull distribution, Mathematics, Distance based

Abstract

The use of flat or weakly informative priors is popular due to the objective a priori belief in the absence of strong prior information. In the case of the Weibull model the improper uniform, equal parameter gamma and joint Jeffrey's priors for the shape parameter are popular choices. The effects and behaviors of these priors have yet to be established from a modeling viewpoint, especially their ability to reduce to the simpler exponential model. In this work we propose a new principled prior for the shape parameter of the Weibull model, originating from a prior on the distance function, and advocate this new prior as a principled choice in the absence of strong prior information. This new prior can then be used in models with a Weibull modeling component, like competing risks, joint and spatial models, to mention a few. This prior is available in the R-INLA for use, and is applied in a joint longitudinal-survival model framework using the INLA method.

Published

2020

31. Efficient Quantile Tracking Using an Oracle

Author

Hugo L. Hammer, Anis Yazidi, Michael A. Riegler, and Håvard Rue

Subjects

Methodology (stat.ME), FOS: Computer and information sciences, Statistics - Machine Learning, Artificial Intelligence, Incremental quantile estimators, Machine Learning (stat.ML), Concept drift, Statistics - Computation, Data mining, Real-time tracking, Statistics - Methodology, Computation (stat.CO)

Abstract

For incremental quantile estimators the step size and possibly other tuning parameters must be carefully set. However, little attention has been given on how to set these values in an online manner. In this article we suggest two novel procedures that address this issue. The core part of the procedures is to estimate the current tracking mean squared error (MSE). The MSE is decomposed in tracking variance and bias and novel and efficient procedures to estimate these quantities are presented. It is shown that estimation bias can be tracked by associating it with the portion of observations below the quantile estimates. The first procedure runs an ensemble of $L$ quantile estimators for wide range of values of the tuning parameters and typically around $L = 100$. In each iteration an oracle selects the best estimate by the guidance of the estimated MSEs. The second method only runs an ensemble of $L = 3$ estimators and thus the values of the tuning parameters need from time to time to be adjusted for the running estimators. The procedures have a low memory foot print of $8L$ and a computational complexity of $8L$ per iteration. The experiments show that the procedures are highly efficient and track quantiles with an error close to the theoretical optimum. The Oracle approach performs best, but comes with higher computational cost. The procedures were further applied to a massive real-life data stream of tweets and proofed real world applicability of them.

Published

2020

32. An approximate fractional Gaussian noise model with $$\mathcal {O}(n)$$ O ( n ) computational cost

Author

Eirik Myrvoll-Nilsen, Håvard Rue, and Sigrunn Holbek Sørbye

Subjects

Statistics and Probability, Markov chain, Covariance matrix, Gaussian, Autocorrelation, 010103 numerical & computational mathematics, 01 natural sciences, Toeplitz matrix, Theoretical Computer Science, 010104 statistics & probability, symbols.namesake, Computational Theory and Mathematics, Autoregressive model, Laplace's method, Gaussian noise, symbols, Applied mathematics, 0101 mathematics, Statistics, Probability and Uncertainty, Mathematics

Abstract

Fractional Gaussian noise (fGn) is a stationary time series model with long-memory properties applied in various fields like econometrics, hydrology and climatology. The computational cost in fitting an fGn model of length n using a likelihood-based approach is $${{\mathcal {O}}}(n^{2})$$ , exploiting the Toeplitz structure of the covariance matrix. In most realistic cases, we do not observe the fGn process directly but only through indirect Gaussian observations, so the Toeplitz structure is easily lost and the computational cost increases to $${{\mathcal {O}}}(n^{3})$$ . This paper presents an approximate fGn model of $${{\mathcal {O}}}(n)$$ computational cost, both with direct and indirect Gaussian observations, with or without conditioning. This is achieved by approximating fGn with a weighted sum of independent first-order autoregressive (AR) processes, fitting the parameters of the approximation to match the autocorrelation function of the fGn model. The resulting approximation is stationary despite being Markov and gives a remarkably accurate fit using only four AR components. Specifically, the given approximate fGn model is incorporated within the class of latent Gaussian models in which Bayesian inference is obtained using the methodology of integrated nested Laplace approximation. The performance of the approximate fGn model is demonstrated in simulations and two real data examples.

Published

2018

33. Estimating multilevel regional variation in excess mortality of cancer patients using integrated nested Laplace approximation

Author

Håvard Rue, Esa Läärä, Timo Hakulinen, Mikko J. Sillanpää, Karri Seppä, and Janne Pitkäniemi

Subjects

Statistics and Probability, Epidemiology, Population, Breast Neoplasms, 01 natural sciences, Standard deviation, 010104 statistics & probability, 03 medical and health sciences, symbols.namesake, 0302 clinical medicine, Statistics, Markov chain Monte Carlo (MCMC), Humans, Poisson Distribution, Registries, 030212 general & internal medicine, Poisson regression, Cities, 0101 mathematics, cancer survival, education, Finland, Demography, Mathematics, Ovarian Neoplasms, education.field_of_study, Models, Statistical, Relative survival, regional variation, Regression analysis, Markov chain Monte Carlo, Random effects model, Survival Analysis, Hospitals, excess mortality, Laplace's method, Small-Area Analysis, symbols, Female, integrated nested Laplace approximation (INLA)

Abstract

Models of excess mortality with random effects were used to estimate regional variation in relative or net survival of cancer patients. Statistical inference for these models based on the Markov chain Monte Carlo (MCMC) methods is computationally intensive and, therefore, not feasible for routine analyses of cancer register data. This study assessed the performance of the integrated nested Laplace approximation (INLA) in monitoring regional variation in cancer survival. Poisson regression model of excess mortality including both spatially correlated and unstructured random effects was fitted to the data of patients diagnosed with ovarian and breast cancer in Finland during 1955–2014 with follow up from 1960 through 2014 by using the period approach with five‐year calendar time windows. We estimated standard deviations associated with variation (i) between hospital districts and (ii) between municipalities within hospital districts. Posterior estimates based on the INLA approach were compared to those based on the MCMC simulation. The estimates of the variation parameters were similar between the two approaches. Variation within hospital districts dominated in the total variation between municipalities. In 2000–2014, the proportion of the average variation within hospital districts was 68% (95% posterior interval: 35–93%) and 82% (60–98%) out of the total variation in ovarian and breast cancer, respectively. In the estimation of regional variation, the INLA approach was accurate, fast, and easy to implement by using the R‐INLA package.

Published

2018

34. Varying coefficient models for areal data

Author

Maria Franco-Villoria, Massimo Ventrucci, Håvard Rue, Maria Franco-Villoria, Massimo Ventrucci, and Håvard Rue

Subjects

Varying coefficient models, PC priors, Bayesian, INLA

Published

2018

35. Constructing priors for functional linear regression models

Author

Maria Franco-Villoria, Massimo Ventrucci, Håvard Rue, Maria Franco-Villoria, Massimo Ventrucci, and Håvard Rue

Subjects

INLA, Flexible regression, Functional regression, PC prior

Published

2018

36. Bayesian bivariate meta-analysis of diagnostic test studies with interpretable priors

Author

Håvard Rue, Andrea Riebler, and Jingyi Guo

Subjects

Statistics and Probability, Hyperparameter, Epidemiology, business.industry, Bayesian probability, Variance (accounting), Bivariate analysis, Machine learning, computer.software_genre, Bayesian inference, 01 natural sciences, 010104 statistics & probability, 03 medical and health sciences, Bayes' theorem, 0302 clinical medicine, Frequentist inference, Prior probability, 030212 general & internal medicine, Artificial intelligence, 0101 mathematics, business, computer, Mathematics

Abstract

In a bivariate meta-analysis, the number of diagnostic studies involved is often very low so that frequentist methods may result in problems. Using Bayesian inference is particularly attractive as informative priors that add a small amount of information can stabilise the analysis without overwhelming the data. However, Bayesian analysis is often computationally demanding and the selection of the prior for the covariance matrix of the bivariate structure is crucial with little data. The integrated nested Laplace approximations method provides an efficient solution to the computational issues by avoiding any sampling, but the important question of priors remain. We explore the penalised complexity (PC) prior framework for specifying informative priors for the variance parameters and the correlation parameter. PC priors facilitate model interpretation and hyperparameter specification as expert knowledge can be incorporated intuitively. We conduct a simulation study to compare the properties and behaviour of differently defined PC priors to currently used priors in the field. The simulation study shows that the PC prior seems beneficial for the variance parameters. The use of PC priors for the correlation parameter results in more precise estimates when specified in a sensible neighbourhood around the truth. To investigate the usage of PC priors in practice, we reanalyse a meta-analysis using the telomerase marker for the diagnosis of bladder cancer and compare the results with those obtained by other commonly used modelling approaches. Copyright © 2017 John Wiley & Sons, Ltd.

Published

2017

37. Careful prior specification avoids incautious inference for log-Gaussian Cox point processes

Author

David F. R. P. Burslem, Sigrunn H. S⊘rbye, Håvard Rue, Janine B. Illian, Daniel Simpson, University of St Andrews. Statistics, University of St Andrews. Scottish Oceans Institute, and University of St Andrews. Centre for Research into Ecological & Environmental Modelling

Subjects

0106 biological sciences, Statistics and Probability, Soil map, Spatial point process, History, Soil nutrients, Spatial modelling, Bayesian analysis, Library science, Inference, Penalized complexity prior, 3rd-DAS, 15. Life on land, Tropical forest, 010603 evolutionary biology, 01 natural sciences, Field (geography), Statistics::Computation, 010104 statistics & probability, Statistics::Methodology, QA Mathematics, 0101 mathematics, Statistics, Probability and Uncertainty, QA, R-INLA

Abstract

We acknowledge the principal investigators who were responsible for collecting and analysing the soil maps (Jim Dallin, Robert John, Kyle Harms, Robert Stallard and Joe Yavitt), the funding sources (National Science Foundation grants DEB021104, 021115, 0212284 and 0212818 and Office of International Science and Engineering grant 0314581, the Smithsonian Tropical Research Institute soils initiative and the Center for Tropical Forest Science) and field assistants (Paolo Segre and Juan Di Trani). Hyperprior specifications for random fields in spatial point process modelling can have a major impact on the results. In fitting log-Gaussian Cox processes to rainforest tree species, we consider a reparameterised model combining a spatially structured and an unstructured random field into a single component. This component has one hyperpa- rameter accounting for marginal variance, while an additional hyperparameter governs the fraction of the variance explained by the spatially structured effect. This facilitates inter- pretation of the hyperparameters and significance of covariates is studied for a range of hyperprior specifications. Appropriate scaling makes the analysis invariant to grid resolution. Postprint

Published

2019

38. Intuitive Joint Priors for Variance Parameters

Author

Håvard Rue, Ingeborg Gullikstad Hem, Andrea Riebler, Geir-Arne Fuglstad, and Alexander Knight

Subjects

FOS: Computer and information sciences, Statistics and Probability, Computer science, Inference, Bayesian inference, Machine learning, computer.software_genre, 01 natural sciences, Dirichlet distribution, Methodology (stat.ME), 010104 statistics & probability, symbols.namesake, 0502 economics and business, Prior probability, variance parameters, 0101 mathematics, Additive model, Statistics - Methodology, 050205 econometrics, Hyperparameter, hierarchical variance decomposition, additive models, business.industry, Applied Mathematics, 05 social sciences, Variance (accounting), Tree structure, latent Gaussian models, symbols, joint prior distributions, Artificial intelligence, business, computer, penalised complexity

Abstract

Variance parameters in additive models are typically assigned independent priors that do not account for model structure. We present a new framework for prior selection based on a hierarchical decomposition of the total variance along a tree structure to the individual model components. For each split in the tree, an analyst may be ignorant or have a sound intuition on how to attribute variance to the branches. In the former case a Dirichlet prior is appropriate to use, while in the latter case a penalised complexity (PC) prior provides robust shrinkage. A bottom-up combination of the conditional priors results in a proper joint prior. We suggest default values for the hyperparameters and offer intuitive statements for eliciting the hyperparameters based on expert knowledge. The prior framework is applicable for R packages for Bayesian inference such as INLA and RStan. Three simulation studies show that, in terms of the application-specific measures of interest, PC priors improve inference over Dirichlet priors when used to penalise different levels of complexity in splits. However, when expressing ignorance in a split, Dirichlet priors perform equally well and are preferred for their simplicity. We find that assigning current state-of-the-art default priors for each variance parameter individually is less transparent and does not perform better than using the proposed joint priors. We demonstrate practical use of the new framework by analysing spatial heterogeneity in neonatal mortality in Kenya in 2010-2014 based on complex survey data., Comment: 64 pages, 33 figures

Published

2019

39. Advanced Spatial Modeling with Stochastic Partial Differential Equations Using R and INLA

Author

Elias Krainski, Virgilio Gómez-Rubio, Haakon Bakka, Amanda Lenzi, Daniela Castro-Camilo, Daniel Simpson, Finn Lindgren, and Håvard Rue

Published

2018

40. Spatio-temporal models for georeferenced unemployment data

Author

Luis Correia, Soraia Pereira, Kamil Feridun Turkman, and Håvard Rue

Subjects

Statistics and Probability, Estimation, education.field_of_study, media_common.quotation_subject, 0208 environmental biotechnology, Population, Sampling (statistics), 02 engineering and technology, Management, Monitoring, Policy and Law, 01 natural sciences, Point process, 020801 environmental engineering, Unit (housing), Cox process, 010104 statistics & probability, Geography, Unemployment, Econometrics, 0101 mathematics, Computers in Earth Sciences, education, Realization (probability), media_common

Abstract

The Portuguese National Statistical Institute is responsible for estimating and publishing quarterly labour market figures at national level for both NUTS I and NUTS II regions. Over recent years it has become increasinglyimportant to identify these figures at more disaggregated levels. However, based on the established direct estimation method, it is not possible to produce satisfactorily precise estimates at higher spatial resolutions. From the 4th quarter of 2014 onwards, all the sampling units, namely the residential buildings, of the Portuguese Labour Force Survey (PLFS) were georeferenced. To take full advantage of this information, Pereira et al. (2019) proposed applying a spatial marked point process approach to unemployment estimation, in which the estimation of the unemployment intensity becomes the focal point. There, the sampling units were assumed to be a realization of a spatial point process, specifically a log Gaussian Cox process, with the number of unemployed in each unit being their respective marks. Recently, further information on the geo-referenced locations of all units of the population, namely all residential buildings in the national territory, became available. Consequently, it is no longer necessary to model the spatial configuration of the units of the population. Thus, we propose a new point referenced model for the marks based on the sampled units and extrapolate this to all units of the population. As expected, this extra information, and as a consequence the new model itself, produce estimates with higher precision.

Published

2020

41. Advanced Spatial Modeling with Stochastic Partial Differential Equations Using R and INLA

Author

Elias Krainski, Virgilio Gómez-Rubio, Haakon Bakka, Amanda Lenzi, Daniela Castro-Camilo, Daniel Simpson, Finn Lindgren, Håvard Rue, Elias Krainski, Virgilio Gómez-Rubio, Haakon Bakka, Amanda Lenzi, Daniela Castro-Camilo, Daniel Simpson, Finn Lindgren, and Håvard Rue

Subjects

Stochastic processes, Mathematical models, Stochastic differential equations, R (Computer program language), Laplace transformation

Abstract

Modeling spatial and spatio-temporal continuous processes is an important and challenging problem in spatial statistics. Advanced Spatial Modeling with Stochastic Partial Differential Equations Using R and INLA describes in detail the stochastic partial differential equations (SPDE) approach for modeling continuous spatial processes with a Matérn covariance, which has been implemented using the integrated nested Laplace approximation (INLA) in the R-INLA package. Key concepts about modeling spatial processes and the SPDE approach are explained with examples using simulated data and real applications.This book has been authored by leading experts in spatial statistics, including the main developers of the INLA and SPDE methodologies and the R-INLA package. It also includes a wide range of applications:• Spatial and spatio-temporal models for continuous outcomes• Analysis of spatial and spatio-temporal point patterns• Coregionalization spatial and spatio-temporal models• Measurement error spatial models• Modeling preferential sampling• Spatial and spatio-temporal models with physical barriers• Survival analysis with spatial effects• Dynamic space-time regression• Spatial and spatio-temporal models for extremes• Hurdle models with spatial effects• Penalized Complexity priors for spatial modelsAll the examples in the book are fully reproducible. Further information about this book, as well as the R code and datasets used, is available from the book website at http://www.r-inla.org/spde-book.The tools described in this book will be useful to researchers in many fields such as biostatistics, spatial statistics, environmental sciences, epidemiology, ecology and others. Graduate and Ph.D. students will also find this book and associated files a valuable resource to learn INLA and the SPDE approach for spatial modeling.

Published

2019

42. Spatial modelling with R-INLA: A review

Author

Janine B. Illian, Daniel Simpson, Finn Lindgren, Geir-Arne Fuglstad, Elias Teixeira Krainski, Håvard Rue, David Bolin, Haakon Bakka, and Andrea Riebler

Subjects

Statistics and Probability, Random field, 010504 meteorology & atmospheric sciences, Computer science, Gaussian, Bayesian probability, Inference, Statistical model, Random effects model, 01 natural sciences, Stochastic partial differential equation, 010104 statistics & probability, symbols.namesake, symbols, 0101 mathematics, Spatial analysis, Algorithm, 0105 earth and related environmental sciences

Abstract

Coming up with Bayesian models for spatial data is easy, but performing inference with them can be challenging. Writing fast inference code for a complex spatial model with realistically‐sized datasets from scratch is time‐consuming, and if changes are made to the model, there is little guarantee that the code performs well. The key advantages of R‐INLA are the ease with which complex models can be created and modified, without the need to write complex code, and the speed at which inference can be done even for spatial problems with hundreds of thousands of observations. R‐INLA handles latent Gaussian models, where fixed effects, structured and unstructured Gaussian random effects are combined linearly in a linear predictor, and the elements of the linear predictor are observed through one or more likelihoods. The structured random effects can be both standard areal model such as the Besag and the BYM models, and geostatistical models from a subset of the Matérn Gaussian random fields. In this review, we discuss the large success of spatial modeling with R‐INLA and the types of spatial models that can be fitted, we give an overview of recent developments for areal models, and we give an overview of the stochastic partial differential equation (SPDE) approach and some of the ways it can be extended beyond the assumptions of isotropy and separability. In particular, we describe how slight changes to the SPDE approach leads to straight‐forward approaches for nonstationary spatial models and nonseparable space–time models. Locked until 5.7.2019 due to copyright restrictions. This is the peer reviewed version of an article, which has been published in final form at [https://doi.org/10.1002/wics.1443]. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Self-Archiving.

Published

2018

43. You Just Keep on Pushing My Love over the Borderline: A Rejoinder

Author

Daniel Simpson, Håvard Rue, Andrea Riebler, Sigrunn Holbek Sørbye, and Thiago G. Martins

Subjects

0301 basic medicine, Statistics and Probability, Psychoanalysis, General Mathematics, 01 natural sciences, VDP::Matematikk og Naturvitenskap: 400::Matematikk: 410, VDP::Mathematics and natural science: 400::Mathematics: 410, 010104 statistics & probability, 03 medical and health sciences, 030104 developmental biology, 0101 mathematics, Statistics, Probability and Uncertainty, Mathematics

Abstract

Source at https://doi.org/10.1214/17-sts576rej. INTRODUCTION: The point of departure for our paper is that most modern statistical models are built to be flexible enough to model diverse data generating mechanisms. Good statistical practice requires us to limit this flexibility, which is typically controlled by a small number of parameters, to the amount “needed” to model the data at hand. The Bayesian framework provides a natural method for doing this although, as DD points out, this trend for penalising model complexity casts a broad shadow over all of modern statistics and data science.The PC prior framework argues for setting priors on these flexibility parameters that are specifically built to penalise a certain type of complexity and avoid overfitting. The discussants raised various points about this core idea. First, DD pointed out that while over-fitting a model is a bad thing, under-fitting is not better: we do not want Occam’s razor to slit our throat. We saw this behaviour when using a half-Normal prior on the distance, while the exponential prior does not lead to obvious attenuation of the estimates. This is confirmed experimentally by Klein and Kneib (2016).

Published

2017

44. A Bayesian approach to estimate the biomass of anchovies off the coast of Perú

Author

Zaida C. Quiroz, Marcos O. Prates, and Håvard Rue

Subjects

Statistics and Probability, education.field_of_study, Biomass (ecology), General Immunology and Microbiology, biology, Applied Mathematics, Bayesian probability, Population, Context (language use), General Medicine, Geostatistics, biology.organism_classification, General Biochemistry, Genetics and Molecular Biology, Bayes' theorem, Engraulis, Geography, Anchovy, Statistics, General Agricultural and Biological Sciences, education

Abstract

The Northern Humboldt Current System (NHCS) is the world's most productive ecosystem in terms of fish. In particular, the Peruvian anchovy (Engraulis ringens) is the major prey of the main top predators, like seabirds, fish, humans, and other mammals. In this context, it is important to understand the dynamics of the anchovy distribution to preserve it as well as to exploit its economic capacities. Using the data collected by the "Instituto del Mar del Peru" (IMARPE) during a scientific survey in 2005, we present a statistical analysis that has as main goals: (i) to adapt to the characteristics of the sampled data, such as spatial dependence, high proportions of zeros and big size of samples; (ii) to provide important insights on the dynamics of the anchovy population; and (iii) to propose a model for estimation and prediction of anchovy biomass in the NHCS offshore from Peru. These data were analyzed in a Bayesian framework using the integrated nested Laplace approximation (INLA) method. Further, to select the best model and to study the predictive power of each model, we performed model comparisons and predictive checks, respectively. Finally, we carried out a Bayesian spatial influence diagnostic for the preferred model.

Published

2014

45. Extending Integrated Nested Laplace Approximation to a Class of Near-Gaussian Latent Models

Author

Thiago G. Martins and Håvard Rue

Subjects

Statistics and Probability, Mathematical optimization, Gaussian, Markov chain Monte Carlo, Field (computer science), symbols.namesake, Distribution (mathematics), Laplace's method, Component (UML), symbols, Applied mathematics, Fraction (mathematics), Statistics, Probability and Uncertainty, Scope (computer science), Mathematics

Abstract

This work extends the integrated nested Laplace approximation (INLA) method to latent models outside the scope of latent Gaussian models, where independent components of the latent field can have a near-Gaussian distribution. The proposed methodology is an essential component of a bigger project that aims to extend the R package INLA in order to allow the user to add flexibility and challenge the Gaussian assumptions of some of the model components in a straightforward and intuitive way. Our approach is applied to two examples, and the results are compared with that obtained by Markov chain Monte Carlo, showing similar accuracy with only a small fraction of computational time. Implementation of the proposed extension is available in the R-INLA package.

Published

2014

46. Spatial modeling of Audubon Christmas Bird Counts reveals fine‐scale patterns and drivers of relative abundance trends

Author

Nicole L. Michel, Håvard Rue, and Timothy D. Meehan

Subjects

Geography, Ecology, Scale (ratio), Bayesian hierarchical modeling, Physical geography, Relative species abundance, Ecology, Evolution, Behavior and Systematics

Published

2019

47. Geostatistical Survival Models for Environmental Risk Assessment with Large Retrospective Cohorts

Author

Håvard Rue, Huan Jiang, Patrick Brown, and Silvia Emiko Shimakura

Subjects

Statistics and Probability, Economics and Econometrics, education.field_of_study, Markov chain, Computer science, Population, Retrospective cohort study, Bayesian inference, Statistics, Econometrics, Statistical inference, Statistics, Probability and Uncertainty, Spatial dependence, Risk assessment, education, Social Sciences (miscellaneous), Survival analysis

Abstract

Summary Motivated by the problem of cancer risk assessment near a nuclear power generating station, the paper describes a methodology for fitting a spatially correlated survival model to large retrospective cohort data sets. Retrospective cohorts, which can be assembled inexpensively from population-based health databases, can partially account for lags between exposures and outcome of chronic diseases such as cancer. These data sets overcome one of the principal limitations of cross-sectional spatial analyses, though performing statistical inference requires accommodating censored and truncated event times as well as spatial dependence. The use of spatial survival models for large retrospective cohorts is described, and Bayesian inference using Markov random-field approximations and integrated nested Laplace approximations is presented. The method is applied to data from individuals living near Pickering Nuclear Generating Station in Canada, showing that the effect of ambient radiation on cancer is not statistically significant.

Published

2013

48. Discussion of ‘Beyond mean regression’

Author

Håvard Rue, Janine B. Illian, Thiago G. Martins, Óli Páll Geirsson, and Daniel Simpson

Subjects

Statistics and Probability, Statistics, Statistics, Probability and Uncertainty, Regression, Mathematics

Published

2013

49. Bayesian Computing with INLA: A Review

Author

Janine B. Illian, Håvard Rue, Andrea Riebler, Finn Lindgren, Daniel Simpson, and Sigrunn Holbek Sørbye

Subjects

FOS: Computer and information sciences, Statistics and Probability, Mathematical optimization, 010504 meteorology & atmospheric sciences, VDP::Mathematics and natural science: 400::Mathematics: 410::Statistics: 412, Gaussian, Bayesian probability, VDP::Matematikk og Naturvitenskap: 400::Matematikk: 410::Statistikk: 412, Bayesian inference, 01 natural sciences, Methodology (stat.ME), 010104 statistics & probability, symbols.namesake, Applied mathematics, 0101 mathematics, Statistics - Methodology, 0105 earth and related environmental sciences, Mathematics, Sparse matrix, Laplace transform, Statistical model, Statistics::Computation, Bayesian statistics, Laplace's method, symbols, Statistics, Probability and Uncertainty

Abstract

The key operation in Bayesian inference, is to compute high-dimensional integrals. An old approximate technique is the Laplace method or approximation, which dates back to Pierre- Simon Laplace (1774). This simple idea approximates the integrand with a second order Taylor expansion around the mode and computes the integral analytically. By developing a nested version of this classical idea, combined with modern numerical techniques for sparse matrices, we obtain the approach of Integrated Nested Laplace Approximations (INLA) to do approximate Bayesian inference for latent Gaussian models (LGMs). LGMs represent an important model-abstraction for Bayesian inference and include a large proportion of the statistical models used today. In this review, we will discuss the reasons for the success of the INLA-approach, the R-INLA package, why it is so accurate, why the approximations are very quick to compute and why LGMs make such a useful concept for Bayesian computing., 28 pages, 7 figures

Published

2016

50. An intuitive Bayesian spatial model for disease mapping that accounts for scaling

Author

Håvard Rue, Sigrunn Holbek Sørbye, Daniel Simpson, and Andrea Riebler

Subjects

Statistics and Probability, FOS: Computer and information sciences, Epidemiology, Computer science, Bayesian probability, Normal Distribution, Machine learning, computer.software_genre, 01 natural sciences, Interpretation (model theory), Methodology (stat.ME), 010104 statistics & probability, 03 medical and health sciences, 0302 clinical medicine, Health Information Management, Component (UML), Prior probability, Bayesian hierarchical modeling, 030212 general & internal medicine, 0101 mathematics, Statistics - Methodology, Hyperparameter, business.industry, Bayes Theorem, Random effects model, Markov Chains, Epidemiological Monitoring, Graph (abstract data type), Artificial intelligence, business, computer

Abstract

In recent years, disease mapping studies have become a routine application within geographical epidemiology and are typically analysed within a Bayesian hierarchical model formulation. A variety of model formulations for the latent level have been proposed but all come with inherent issues. In the classical BYM model, the spatially structured component cannot be seen independently from the unstructured component. This makes prior definitions for the hyperparameters of the two random effects challenging. There are alternative model formulations that address this confounding, however, the issue on how to choose interpretable hyperpriors is still unsolved. Here, we discuss a recently proposed parameterisation of the BYM model that leads to improved parameter control as the hyperparameters can be seen independently from each other. Furthermore, the need for a scaled spatial component is addressed, which facilitates assignment of interpretable hyperpriors and make these transferable between spatial applications with different graph structures. We provide implementation details for the new model formulation which preserve sparsity properties, and we investigate systematically the model performance and compare it to existing parameterisations. Through a simulation study, we show that the new model performs well, both showing good learning abilities and good shrinkage behaviour. In terms of model choice criteria, the proposed model performs at least equally well as existing parameterisations, but only the new formulation offers parameters that are interpretable and hyperpriors that have a clear meaning., Comment: 24 pages, 6 figures, 5 tables

Published

2016