PM 2.5 ∕ PM 10 ratio prediction based on a long short-term memory neural network in Wuhan, China

Wu, Xueling; Wang, Ying; He, Siyuan; Wu, Zhongfang

Air pollution is a serious problem in China that urgently needs to be addressed. Air pollution has a great impact on the lives of citizens and on urban development. The particulate matter (PM) value is usually used to indicate the degree of air pollution. In addition to that of PMinline-formula2.5 and PMinline-formula10, the use of the PMinline-formula2.5inline-formula∕ PMinline-formula10 ratio as an indicator and assessor of air pollution has also become more widespread. This ratio reflects the air pollution conditions and pollution sources. In this paper, a better composite prediction system aimed at improving the accuracy and spatiotemporal applicability of PMinline-formula2.5inline-formula∕ PMinline-formula10 was proposed. First, the aerosol optical depth (AOD) in 2017 in Wuhan was obtained based on Moderate Resolution Imaging Spectroradiometer (MODIS) images, with a 1 km spatial resolution, by using the dense dark vegetation (DDV) method. Second, the AOD was corrected by calculating the planetary boundary layer height (PBLH) and relative humidity (RH). Third, the coefficient of determination of the optimal subset selection was used to select the factor with the highest correlation with PMinline-formula2.5inline-formula∕ PMinline-formula10 from meteorological factors and gaseous pollutants. Then, PMinline-formula2.5inline-formula∕ PMinline-formula10 predictions based on time, space, and random patterns were obtained by using nine factors (the corrected AOD, meteorological data, and gaseous pollutant data) with the long short-term memory (LSTM) neural network method, which is a dynamic model that remembers historical information and applies it to the current output. Finally, the LSTM model prediction results were compared and analyzed with the results of other intelligent models. The results showed that the LSTM model had significant advantages in the average, maximum, and minimum accuracy and the stability of PMinline-formula2.5inline-formula∕ PMinline-formula10 prediction.

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Wu, Xueling / Wang, Ying / He, Siyuan / et al: PM2.5 ∕ PM10 ratio prediction based on a long short-term memory neural network in Wuhan, China. 2020. Copernicus Publications.

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