A neural network-based land use regression model to estimate spatial-temporal variability of nitrogen dioxide

Pei Yi Wong, Chih Da Wu, Huey Jen Su

研究成果: Paper

摘要

Nitrogen dioxide (NO2) is a kind of highly reactive gas and secondary pollutant mainly from burning fossil fuels, which were predominant species in vehicle exhaust. Since traffic volume density is heavy and large number of temples and restaurants were densely distributed in Taiwan. The high concentration of NO2 may cause adverse effects on respiratory system. To estimate NO2 concentration more accurately, this study aimed to utilize a neural network-based land use regression model to assess the spatial-temporal variability. Daily average NO2 data were collected from 70 fixed air quality monitoring stations in Taiwan main island which were established by Taiwan Environment Protective Administration. Totally, around 0.41 million observations were collected for our analysis. Several datasets were collected for obtaining spatial predictor variables, including EPA environmental resources dataset, meteorological dataset, land-use inventory, landmark dataset, digital road network map, DTM, MODIS NDVI dataset, and thermal power plant distribution dataset. To establish the integrated approach, conventional land-use regression (LUR) was first used to identify the important predictors variables. Then a deep neural network (DNN) algorithm was applied to fit the prediction model. 10-fold cross validation and external data verification methods were used to further confirm the robustness of model performance. The results showed that, the developed conventional LUR model captured 60% of NO2 variation. Of the 11 variables selected by the stepwise variable selection procedure, PM10, SO2, O3 explained 18%, 7% and 5% NO2 variation, respectively. After integrating DNN algorithm with conventional LUR method, the model explanatory power was increased to 85%, with a 25% improved in model performance. Consistent findings were obtained from the 10-fold cross validation, while the cross-validated R2 was increased from 61% to 83%, and root-mean-square error (RMSE) was decreased from 6.56 ppb to 4.34 ppb. This study demonstrates the value of incorporating the conventional LUR model and DNN algorithm in estimating spatial-temporal variability of NO2 exposure.

原文English
出版狀態Published - 2020 一月 1
事件40th Asian Conference on Remote Sensing: Progress of Remote Sensing Technology for Smart Future, ACRS 2019 - Daejeon, Korea, Republic of
持續時間: 2019 十月 142019 十月 18

Conference

Conference40th Asian Conference on Remote Sensing: Progress of Remote Sensing Technology for Smart Future, ACRS 2019
國家Korea, Republic of
城市Daejeon
期間19-10-1419-10-18

    指紋

All Science Journal Classification (ASJC) codes

  • Information Systems

引用此

Wong, P. Y., Wu, C. D., & Su, H. J. (2020). A neural network-based land use regression model to estimate spatial-temporal variability of nitrogen dioxide. 論文發表於 40th Asian Conference on Remote Sensing: Progress of Remote Sensing Technology for Smart Future, ACRS 2019, Daejeon, Korea, Republic of.