Abstract

Effective measurement of exposure to air pollution, not least NO2, for epidemiological studies along with the need to better management and control of air pollution in urban areas ask for precise interpolation and determination of the concentration of pollutants in nonmonitored spots. A variety of approaches have been developed and used. This paper aims to propose, develop, and test a spatial predictive model based on multivariate adaptive regression splines (MARS) and principle component analysis (PCA) to determine the concentration of NO2 in Tehran, as a case study. To increase the accuracy of the model, spatial data (population, road network and point of interests such as petroleum stations and green spaces) and meteorological data (including temperature, pressure, wind speed and relative humidity) have also been used as independent variables, alongside air quality measurement data gathered by the monitoring stations. The outputs of the proposed model are evaluated against reference interpolation techniques including inverse distance weighting, thin plate splines, kriging, cokriging, and MARS3. Interpolation for 12 months showed better accuracies of the proposed model in comparison with the reference methods.

Highlights

  • NO2 has adverse effect on human life and environment

  • In order to increase the accuracy of interpolation and generating high-resolution maps of NO2, this study develops and suggests a new model called PCAMARS which is an extension to multivariate adaptive regression splines (MARS) by principle component analysis (PCA)

  • Leave-One-Out Cross Validation (LOOCV) was used to calculate the root-mean-square error (RMSE) of NO2 interpolation for each specific time

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Summary

Introduction

NO2 has adverse effect on human life and environment. Numerous studies have shown the effect of NO2 exposure on respiratory problems and deterioration of asthmatic patients (Pollution 2010). Either of the following two approaches are used to

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