Spatio-temporal Joint Modelling on Moderate and Extreme Air Pollution in Spain
Very unhealthy air quality is consistently connected with numerous diseases. Appropriate extreme analysis and accurate predictions are in rising demand for exploring potential linked causes and for providing suggestions for the environmental agency in public policy strategy. This paper aims to model the spatial and temporal pattern of both moderate and very poor PM10 concentrations collected from 342 representative monitors distributed throughout mainland Spain from 2017 to 2021. We firstly propose and compare a series of Bayesian generalized extreme models of annual maxima PM10 concentrations, including both the fixed effect as well as the spatio-temporal random effect with the Stochastic Partial Differential Equation approach and a lag-one dynamic auto-regressive component. The similar and different effects of interrelated factors are identified through a joint Bayesian model of annual mean and annual maxima PM10 concentrations, which may bring the power of statistical inference of body data to the tail analysis with implementation in the faster and more accurate Integrated Nested Laplace Approximation (INLA) algorithm with respect to MCMC. Under WAIC, DIC and other criteria, the best model is selected with good predictive ability based on the first four-year data for training and the last-year data for testing. The findings are applied to identify the hot-spot regions with extremely poor quality using excursion functions specified at the grid level. It suggests that the community of Madrid and the northwestern boundary of Spain are likely to be exposed to severe air pollution simultaneously exceeding the warning risk threshold. The joint model also provides evidence that certain predictors (precipitation, vapour pressure and population density) influence comparably while the other predictors (altitude and temperature) impact oppositely in the different scaled PM10 concentrations.
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