【 摘 要 】

One of the significant sources of air pollution and greenhouse gas emissions is the road transportation sector. These emissions are worsened by driving behaviors and network conditions. It is common knowledge that experienced and inexperienced drivers behave differently when operating vehicles. Given the same vehicle in a different timeframe, the drivers’ reactions to similar situations vary, which has a significant influence on the emissions and fuel consumption as their use of acceleration and speed differ. Because the driving patterns of automated vehicles are programmable and provide a platform for smooth driving situations, it is predicted that deploying them might potentially reduce fuel consumption, particularly in urban areas with given traffic situations. This study’s goal is to examine how different degrees of automated vehicles behave when it comes to emissions and how accelerations affect that behavior. Furthermore, the total aggregated emissions on the synthesized urban network are evaluated and compared to legacy vehicles. The emission measuring model is based on the Handbook Emission Factors for Road Transport (HBEFA)3 and is utilized with the Simulation of Urban Mobility (SUMO) microscopic simulation software. The results demonstrate that acceleration value is strongly correlated with individual vehicle emissions. Although the ability of automated vehicles (AVs) to swiftly achieve higher acceleration values has an adverse effect on emissions reduction, it was compensated by the rate of accelerations, which decreases as the automation level increases. According to the simulation results, automated vehicles can reduce carbon monoxide (CO) emissions by 38.56%, carbon dioxide (CO2) emissions by 17.09%, hydrocarbons (HC) emissions by 36.3%, particulate matter (PMx) emissions by 28.12%, nitrogen oxides (NOx) emissions by 19.78% in the most optimistic scenario (that is, when all vehicles are replaced by the upper bound automated vehicles) in the network level.

【 授权许可】

CC BY   
© The Author(s) 2022

【 预 览 】

附件列表

Files	Size	Format	View
RO202305069393099ZK.pdf	3942KB	PDF	download
12982_2022_119_Article_IEq18.gif	1KB	Image	download
12982_2022_119_Article_IEq37.gif	1KB	Image	download
Fig. 2	170KB	Image	download
12982_2022_119_Article_IEq186.gif	1KB	Image	download
12982_2022_119_Article_IEq50.gif	1KB	Image	download
12888_2022_4392_Article_IEq2.gif	1KB	Image	download
12982_2022_119_Article_IEq198.gif	1KB	Image	download
MediaObjects/12888_2022_4418_MOESM2_ESM.pdf	92KB	PDF	download
12982_2022_119_Article_IEq51.gif	1KB	Image	download
12982_2022_119_Article_IEq54.gif	1KB	Image	download
12982_2022_119_Article_IEq55.gif	1KB	Image	download
12982_2022_119_Article_IEq56.gif	1KB	Image	download
12982_2022_119_Article_IEq57.gif	1KB	Image	download
12982_2022_119_Article_IEq58.gif	1KB	Image	download
12982_2022_119_Article_IEq59.gif	1KB	Image	download
12982_2022_119_Article_IEq60.gif	1KB	Image	download

【 图 表 】

12982_2022_119_Article_IEq60.gif

12982_2022_119_Article_IEq59.gif

12982_2022_119_Article_IEq58.gif

12982_2022_119_Article_IEq57.gif

12982_2022_119_Article_IEq56.gif

12982_2022_119_Article_IEq55.gif

12982_2022_119_Article_IEq54.gif

12982_2022_119_Article_IEq51.gif

12982_2022_119_Article_IEq198.gif

12888_2022_4392_Article_IEq2.gif

12982_2022_119_Article_IEq50.gif

12982_2022_119_Article_IEq186.gif

Fig. 2

12982_2022_119_Article_IEq37.gif

12982_2022_119_Article_IEq18.gif

【 参考文献 】

• [1]
• [2]
• [3]
• [4]
• [5]
• [6]
• [7]
• [8]
• [9]
• [10]
• [11]
• [12]
• [13]
• [14]
• [15]
• [16]
• [17]
• [18]
• [19]
• [20]
• [21]
• [22]
• [23]
• [24]
• [25]
• [26]
• [27]
• [28]
• [29]
• [30]
• [31]
• [32]
• [33]
• [34]
• [35]
• [36]
• [37]
• [38]
• [39]
• [40]
• [41]
• [42]