Abstract
Air pollution risk assessment is complex due to dynamic data change and pollution source distribution. Air quality index concentration level prediction is an effective method of protecting public health by providing the means for an early warning against harmful air pollution. However, air quality index-based prediction is challenging as it depends on several complicated factors resulting from dynamic nonlinear air quality time-series data, such as dynamic weather patterns and the verity and distribution of air pollution sources. Subsequently, some minimal models have incorporated a time series-based predicting air quality index at a global level (for a particular city or various cities). These models require interaction between the multiple air pollution sensing sources and additional parameters like wind direction and wind speed. The existing methods in predicting air quality index cannot handle short-term dependencies. These methods also mostly neglect the spatial correlations between the different parameters. Moreover, the assumption of selecting the most recent part of the air quality time series is not valid considering that pollution is cyclic behavior according to various events and conditions due to the high possibility of falling into the trap of local minimum and poor generalization. Therefore, this paper proposes a new air pollution global risk assessment (APGRA) prediction model for an air quality index of spatial correlations to address these issues. The APGRA model incorporates an autoregressive integrated moving average (ARIMA), a Monte Carlo simulation, a collaborative multi-agent system, and a prediction algorithm for reducing air quality index prediction error and processing time. The proposed APGRA model is evaluated based on Malaysia and China real-world air quality datasets. The proposed APGRA model improves the average root mean squared error by 41%, mean and absolute error by 47.10% compared with the conventional ARIMA and ANFIS models.
Highlights
Air quality has drawn much attention in recent years because it seriously affects people’s health
Prediction model performance is evaluated according to accuracy based on mean absolute error (MAE) and root mean square error (RMSE) as well as prediction ability based on the coefficient of determination R2
This paper proposes a Global Air Pollution Risk Assessment (APGRA) model based on a collaborative multi-agent architecture where each city is modeled as a collaborative agent
Summary
Air quality has drawn much attention in recent years because it seriously affects people’s health. People strongly desire air quality prediction, which is Sustainability 2022, 14, 510. Sustainability 2022, 14, 510 challenging as it depends on several complicated factors, such as weather patterns and spatial-temporal dependencies of air quality. Air pollution risk assessment is complex due to its dynamic data and distributed pollution sources [2]. Predicting air quality on weekdays and weekends may be different due to the difference in anthropic emissions [3]. The prediction is challenging because it depends on several complex factors, such as weather patterns, nonlinear time series of air quality data, and distribution of air pollution sources [4,5]. The dynamic data and distributed air pollution risk assessment sources need to be estimated relying on two phases
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