TY - JOUR
T1 - Estimating emissions based on the integration of microscopic traffic simulation and vehicle dynamics model
AU - So, Jaehyun (Jason)
AU - Motamedidehkordi, Nassim
AU - Wu, Yingjie
AU - Busch, Fritz
AU - Choi, Keechoo
N1 - Publisher Copyright:
© 2017 Taylor & Francis Group, LLC.
PY - 2018/4/21
Y1 - 2018/4/21
N2 - This study proposes an integrated simulation approach, which consists of a microscopic traffic simulation model, a vehicle dynamics model, and an emission estimation model, in order to estimate emissions based on more reliable vehicle performance measures. The vehicle performance measures such as engine power and engine speed significantly relate to the amount of emissions, and road curvatures and inclinations are the core inputs affecting these vehicle performance measures. Therefore, providing reliable vehicle performance measures reflecting the road geometric attributes is critical for a reliable emission estimation. This study proposes to use the microscopic traffic simulation model for generating vehicle trajectories, which is advantageous in modeling various traffic situations, and the vehicle dynamics model for producing the vehicle performance measures based on the vehicle trajectories. Finally, the outputs from the vehicle dynamics model are fed into the emission estimation model to compute emission measures. This study conducted a case-study using two road sections, one is a hypothesized road section, including various curvatures and inclinations with regular variations, and the other is a Kesselberg road section, which is an actual geometry in Bayern, Germany. The emission measures are estimated in these case-study road sections using both an existing simulation approach and the proposed integrated simulation approach. The difference between these two emission estimation approaches is discussed in terms of the emission measures, including fuel consumption, nitrogen oxides, and particulate matters.
AB - This study proposes an integrated simulation approach, which consists of a microscopic traffic simulation model, a vehicle dynamics model, and an emission estimation model, in order to estimate emissions based on more reliable vehicle performance measures. The vehicle performance measures such as engine power and engine speed significantly relate to the amount of emissions, and road curvatures and inclinations are the core inputs affecting these vehicle performance measures. Therefore, providing reliable vehicle performance measures reflecting the road geometric attributes is critical for a reliable emission estimation. This study proposes to use the microscopic traffic simulation model for generating vehicle trajectories, which is advantageous in modeling various traffic situations, and the vehicle dynamics model for producing the vehicle performance measures based on the vehicle trajectories. Finally, the outputs from the vehicle dynamics model are fed into the emission estimation model to compute emission measures. This study conducted a case-study using two road sections, one is a hypothesized road section, including various curvatures and inclinations with regular variations, and the other is a Kesselberg road section, which is an actual geometry in Bayern, Germany. The emission measures are estimated in these case-study road sections using both an existing simulation approach and the proposed integrated simulation approach. The difference between these two emission estimation approaches is discussed in terms of the emission measures, including fuel consumption, nitrogen oxides, and particulate matters.
KW - Curvature
KW - emission
KW - inclination
KW - microscopic traffic simulation
KW - vehicle dynamics
UR - http://www.scopus.com/inward/record.url?scp=85029439439&partnerID=8YFLogxK
U2 - 10.1080/15568318.2017.1363328
DO - 10.1080/15568318.2017.1363328
M3 - Article
AN - SCOPUS:85029439439
SN - 1556-8318
VL - 12
SP - 286
EP - 298
JO - International Journal of Sustainable Transportation
JF - International Journal of Sustainable Transportation
IS - 4
ER -