TY - GEN
T1 - Simulation-based Optimization of Autonomous Driving Behaviors
AU - Sadid, Hashmatullah
AU - Qurashi, Moeid
AU - Antoniou, Constantinos
N1 - Publisher Copyright:
© 2022 IEEE.
PY - 2022
Y1 - 2022
N2 - Microscopic traffic models (MTMs) are widely used for assessing the impacts of autonomous and connected autonomous vehicles (AVs/CAVs). These models use car following (CF) and lane changing models to replicate the AV and CAV driving behaviors. Several studies attempt to replicate the accurate configuration of these behaviors (especially CF behavior) with many state-of-the-art modeling methods. However, they need to define certain parameters either based on assumptions or estimation by trajectory data from the limited field experiment of AVs and CAVs, and the impacts prediction accuracy depends on the definition of these parameters. For human-driven vehicles, these parameters mimic human drivers, whereas, for AVs and CAVs, most of these parameters could be controlled by an agent (AV and CAV). Therefore, it is possible to train AVs and CAVs to behave in a way that could potentially enhance their related impacts, e.g., traffic efficiency, emissions, and safety. Thus, this paper proposes an optimization framework that tends to find sets of optimized driving parameters for AVs and CAVs under different varying scenarios to achieve pre-defined policy targets (e.g., reducing travel time, number of conflicts). The proposed framework comprises an optimization module and a simulation environment. The differential evolution (DE) method is used within the optimization module to find the optimal values of the CF parameters. The simulation environment is a SUMO-based platform where several simulations are run under certain scenario conditions. An experimental setup is designed to apply the proposed framework under different scenarios of mixed traffic and demand situations. The findings of this study reveal that safety could be potentially improved by optimized values of CF model parameters. For each policy, where higher weight is allocated to safety, generated optimized parameters significantly improve safety as well as efficiency.
AB - Microscopic traffic models (MTMs) are widely used for assessing the impacts of autonomous and connected autonomous vehicles (AVs/CAVs). These models use car following (CF) and lane changing models to replicate the AV and CAV driving behaviors. Several studies attempt to replicate the accurate configuration of these behaviors (especially CF behavior) with many state-of-the-art modeling methods. However, they need to define certain parameters either based on assumptions or estimation by trajectory data from the limited field experiment of AVs and CAVs, and the impacts prediction accuracy depends on the definition of these parameters. For human-driven vehicles, these parameters mimic human drivers, whereas, for AVs and CAVs, most of these parameters could be controlled by an agent (AV and CAV). Therefore, it is possible to train AVs and CAVs to behave in a way that could potentially enhance their related impacts, e.g., traffic efficiency, emissions, and safety. Thus, this paper proposes an optimization framework that tends to find sets of optimized driving parameters for AVs and CAVs under different varying scenarios to achieve pre-defined policy targets (e.g., reducing travel time, number of conflicts). The proposed framework comprises an optimization module and a simulation environment. The differential evolution (DE) method is used within the optimization module to find the optimal values of the CF parameters. The simulation environment is a SUMO-based platform where several simulations are run under certain scenario conditions. An experimental setup is designed to apply the proposed framework under different scenarios of mixed traffic and demand situations. The findings of this study reveal that safety could be potentially improved by optimized values of CF model parameters. For each policy, where higher weight is allocated to safety, generated optimized parameters significantly improve safety as well as efficiency.
KW - Autonomous vehicles
KW - microscopic modelling
KW - optimization
KW - traffic safety
UR - http://www.scopus.com/inward/record.url?scp=85141850377&partnerID=8YFLogxK
U2 - 10.1109/ITSC55140.2022.9922604
DO - 10.1109/ITSC55140.2022.9922604
M3 - Conference contribution
AN - SCOPUS:85141850377
T3 - IEEE Conference on Intelligent Transportation Systems, Proceedings, ITSC
SP - 4101
EP - 4108
BT - 2022 IEEE 25th International Conference on Intelligent Transportation Systems, ITSC 2022
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 25th IEEE International Conference on Intelligent Transportation Systems, ITSC 2022
Y2 - 8 October 2022 through 12 October 2022
ER -