Spatial interpolation of air pollution measurements using CORINE land cover data

• Published in: Atmospheric environment (1994) Vol. 42; no. 20; pp. 4884 - 4903
• Main Authors: Janssen, Stijn, Dumont, Gerwin, Fierens, Frans, Mensink, Clemens
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 01.06.2008; Elsevier Science
• Subjects: Air quality assessment; Analysis methods; Applied sciences; Atmospheric pollution; CORINE land cover; Exact sciences and technology; Interpolation model; Kriging; Pollution; Belgium; Europe; Air quality assessment; Interpolation model; Kriging; CORINE land cover; Cartography; Geostatistics; Ozone; Air quality; Real time system; Land use; Coarse particle; Interpolation; Maps; Surveillance; Aerosols; Air pollution; Measuring network; Nitrogen dioxide
• ISSN: 1352-2310; 1873-2844
• DOI: 10.1016/j.atmosenv.2008.02.043

Real-time assessment of the ambient air quality has gained an increased interest in recent years. To give support to this evolution, the statistical air pollution interpolation model RIO is developed. Due to the very low computational cost, this interpolation model is an efficient tool for an environment agency when performing real-time air quality assessment. Beside this, a reliable interpolation model can be used to produce analysed maps of historical data records as well. Such maps are essential for correctly checking compliance with population exposure limit values as foreseen by the new EU Air Quality Directive. RIO is an interpolation model that can be classified as a detrended Kriging model. In a first step, the local character of the air pollution sampling values is removed in a detrending procedure. Subsequently, the site-independent data is interpolated by an Ordinary Kriging scheme. Finally, in a re-trending step, a local bias is added to the Kriging interpolation results. As spatially resolved driving force in the detrending process, a land use indicator is developed based on the CORINE land cover data set. The indicator is optimized independently for the three pollutants O 3, NO 2 and PM 10. As a result, the RIO model is able to account for the local character of the air pollution phenomenon at locations where no monitoring stations are available. Through a cross-validation procedure the superiority of the RIO model over standard interpolation techniques, such as the Ordinary Kriging is demonstrated. Air quality maps are presented for the three pollutants mentioned and compared to maps based on standard interpolation techniques.