High air pollutant incidents increase people's health risks definitely, and the possibility of immediate harm to health may also increase. At present, more and more countries are beginning to implement short-term plans for air quality management. Our government also revised the "Emergency Prevention Measures for Severe Deterioration of Air Quality" in 2017, by utilizing short-term measures as a mean to reduce the time and concentration of high-concentration event days; however, few studies on short-term contingency measures were found; assessments on short-term measures also faced limitation due to high variation of small-scale emissions and meteorological conditions in a timely manner. The aim of this study is to improve the deficiencies in the assessment of short-term contingency measures. With the northern air quality zone of Taiwan selected as study area, this study analyzed the validity analysis and benefit evaluation of the load reduction of power plant strategy within three weather patterns for target reduction of PM10 and PM2.5 concentration, and a traffic strategy for target reduction of NO2 and O3 concentration. First, the deep learning prediction model simulates the air quality deterioration concentration under the baseline condition (no pollutant reduction action), and the statistical analysis method is used to test the possibility and effectiveness of target pollutant reduction strangies; then, using air the pollutant transport mode simulates the impact range of the power industry and the efficiency in different regions during load shedding. The results showed that the model prediction ability performed extremely well within one hour and three hours after the prediction. The traffic case showed that the zero-car event of short-term plans in the northern air quality zone is indeed the effect of reducing the NO2 and O3 concentration observations on the day, yet the load reduction of power plant strategy is not implemented as the apparent concentration for the PM10 and PM2.5 concentrations. The concentration range was used to explain the difference between the two weather patterns: High Pressure Peripheral Circulation (HPPC) and Warm Area Ahead of a Front (WAF), and the implementation of power plant emission reductions in both weather patterns tended to reduce the concentration of PM10 and PM2.5. HPPC affected areas were more local and the WAF had a relatively average reduction percentage in the whole area, while the High Pressure System Pushing (HPP) type had no obvious load reduction effect. This research uses the deep learning method to explain the real concentration reduction, and assists the air pollutant transport model to explore the scope of impact and reduce the benefit areas. Combining the existing methods and the analysis methods of emerging data sciences, the two aspects of concentration and spatial analysis provide reference for strategy formulation and short-term air quality contingency measures as benefit analysis.