Recently, with the rise of environmental and health consciousness, issues about air pollution in urban areas are gradually attracting attention, especially for PM2.5 that causes the most severe health risk to human beings. Many studies have highlighted the phenomenon of spatial variability in air pollution, indirectly supporting that there are significant differences between residents’ exposure and background levels. Based on such a factor, background levels cannot represent residents’ exposure around a static station. Different from deploying large-scale airbox stations or mobile fixed-point stations with portable instruments to accurately measure residents’ exposures, this study therefore develops an on-board monitoring system (OBMS) based on the IoT technology, which is responsible for real-time PM2.5¬ measurement in urban areas. In addition to PM¬2.5¬, the measured parameters include current time, current location, moving speed, PM1, PM10, ambient temperature and humidity. The OBMS not only achieves the goal of accurate measurement like what static stations can do, but also efficiently measures the PM2.5 levels in space in an economical way, especially that its measuring results can indicate the impacts of traffic pollution and community pollution in urban areas on residents’ exposure. In addition to providing real-time monitoring data on residents’ exposures, it is also important to predict air quality in urban areas based on these kind of monitoring data (however, limited by small data collected by OBMS, the prediction is based on large data collected by airbox stations). Accurate air quality prediction enables government officials and the public to take proper prevention actions in advance. However, it is difficult to accurately evaluate a real situation because accurate pollution data are hard to obtain, chemical reactions of pollutants are complicated, and the ways utilized to describe pollutant transmission are too simple. Thus, many traditional prediction models have their own limitations, making many prediction tasks use statistical methods that are good at finding patterns and rules from big data. Machine learning is one of statistical methods, which has been adopted by many air quality prediction studies. In these studies, data sources generally use under-represented background levels, and the prediction intervals are mostly in hours, which may not be suitable for air quality prediction needed by residents. Therefore, this study proposes to use long short-term memory (LSTM) and gated recurrent unit (GRU) as the prediction method. With the real-time airbox data as the main source of data, the Taipei metropolitan area is used as a research area to develop a more detailed forecasting model in which the PM2.5 levels changes in next 6 to 30 minutes are predicted. The predictions are also compared with the data collected by the OBMS. This study confirms that the OBMS can instantly monitor residents’ PM2.5 exposure with smaller time interval, and that using smaller time intervals to predict air quality is feasible. Using the techniques of Internet of Things and machine learning, big data collection, analysis and forecasting can be achieved, decision-makers and people can obtain more accurate information, and the goal of smart cities can be met eventually.