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A study on the most important factors affecting the concentration of particulate matter smaller than 10 microns (PM10) using principal component regression

Document Type : Research article

Authors

1 Department of Environmental Engineering, Yazd University, Yazd, Iran.

2 Department of Statistics, Faculty of Basic Sciences, Yazd University, Yazd, Iran.

Abstract

Background & objectives:
Air particulate matters which have natural and human made origins have significant effects on the climate, the environment and human health.  Several epidemiological studies have shown a direct relationship among the concentrations of suspended particles with different adverse health effects. The general purpose of this research was to determine the most important parameters affecting on the concentration of PM10 in Tajrish station (Tehran) and develop an estimator model for PM10.
Materials & methods: In this study, a model is constructed using principal component regression (PCR) for the relationship between the hourly concentration of particulate matter smaller than 10 microns with meteorological parameters (WD, WS, T, P, H) and air pollution parameters (CO, NO2, SO2, NOx, NMHC, THC) in Tajrish station (Tehran). The results of the performance evaluation of PCR model were measured in training and testing stages using RMSE, MAE, R and IA as statistical indicators.
Results: The results of principal components import into multiple regression model showed that the most important variable affecting on the concentrations of PM10, are air temperature and the wind speed.  Also, CO and SO2 emissions were known as synergic factors for PM10 concentration. The results showed that PCR model is able to estimate 41% of PM10 concentrations in the testing.
 
Conclusion: The principal components regression analysis showed that meteorological parameters are one of most important factors affecting on the reduction of PM10 concentration in Tajrish station (Tehran).

Keywords

References
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Journal of Research in Environmental Health
Volume 2, Issue 2 - Serial Number 6
September 2016
Pages 154-164
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