Abstract
NO2 is a traffic-related air pollutant. Ground NO2monitoring stations measure NO2 concentrations at certain locations and statistical predictive methods have been developed to predict NO2 as a continuous surface. Among them, ensemble tree-based methods have shown to be powerful in capturing nonlinear relationships between NO2 measurements and geospatial predictors but it is unclear if the spatial structure of NO2 is also captured in the response-covariates relationships. We dive into the comparison between spatial and non spatial data models accounting for prediction accuracy, model interpretation and uncertainty quantification. Moreover, we implement two new spatial and a nonspatial methods that have not been applied to air pollution mapping. We implemented our study using national ground station measurements of NO2 in Germany and the Netherlands of 2017. Our results indicate heterogeneous levels of importance of modeling the spatial process in different areas. The prediction intervals predicted with ensemble tree-based methods are more satisfactory than the geostatistical methods. The two new methods implemented each obtained better pre-diction accuracy compared to the original ensemble tree-based and stacking methods. The probabilistic distribution of the spatial random field estimated by the geostatistical methods could provide useful information for analyzing emission sources and the spatial process of observations.
Original language | English (US) |
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Journal | Geographical Analysis |
DOIs | |
State | Published - Jan 17 2023 |
ASJC Scopus subject areas
- Earth-Surface Processes
- Geography, Planning and Development