TY - GEN
T1 - Perimeter Control Using Deep Reinforcement Learning
T2 - 26th IEEE International Conference on Intelligent Transportation Systems, ITSC 2023
AU - Li, Xiaocan
AU - Mercurius, Ray Coden
AU - Taitler, Ayal
AU - Wang, Xiaoyu
AU - Noaeen, Mohammad
AU - Sanner, Scott
AU - Abdulhai, Baher
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023/1/1
Y1 - 2023/1/1
N2 - Perimeter control maintains high traffic efficiency within protected regions by controlling transfer flows among regions to ensure that their traffic densities are below critical values. Existing approaches can be categorized as either model-based or model-free, depending on whether they rely on network transmission models (NTMs) and macroscopic fundamental diagrams (MFDs). Although model-based approaches are more data efficient and have performance guarantees, they are inherently prone to model bias and inaccuracy. For example, NTMs often become imprecise for a large number of protected regions, and MFDs can exhibit scatter and hysteresis that are not captured in existing model-based works. Moreover, no existing studies have employed reinforcement learning for homogeneous flow rate optimization in microscopic simulation, where spatial characteristics, vehicle-level information, and metering realizations - often overlooked in macroscopic simulations - are taken into account. To circumvent issues of model-based approaches and macroscopic simulation, we explore a model-free deep reinforcement learning approach that optimizes the flow rate homogeneously at the perimeter at the microscopic level. Additionally, we investigate different arrangements of the agent's state space to assess the importance of different state variables. Results demonstrate that the model-free reinforcement learning approach without any knowledge of NTMs or MFDs can compete and match the performance of a model-based approach, and exhibits enhanced generalizability and scalability.
AB - Perimeter control maintains high traffic efficiency within protected regions by controlling transfer flows among regions to ensure that their traffic densities are below critical values. Existing approaches can be categorized as either model-based or model-free, depending on whether they rely on network transmission models (NTMs) and macroscopic fundamental diagrams (MFDs). Although model-based approaches are more data efficient and have performance guarantees, they are inherently prone to model bias and inaccuracy. For example, NTMs often become imprecise for a large number of protected regions, and MFDs can exhibit scatter and hysteresis that are not captured in existing model-based works. Moreover, no existing studies have employed reinforcement learning for homogeneous flow rate optimization in microscopic simulation, where spatial characteristics, vehicle-level information, and metering realizations - often overlooked in macroscopic simulations - are taken into account. To circumvent issues of model-based approaches and macroscopic simulation, we explore a model-free deep reinforcement learning approach that optimizes the flow rate homogeneously at the perimeter at the microscopic level. Additionally, we investigate different arrangements of the agent's state space to assess the importance of different state variables. Results demonstrate that the model-free reinforcement learning approach without any knowledge of NTMs or MFDs can compete and match the performance of a model-based approach, and exhibits enhanced generalizability and scalability.
UR - http://www.scopus.com/inward/record.url?scp=85186503217&partnerID=8YFLogxK
U2 - 10.1109/ITSC57777.2023.10422618
DO - 10.1109/ITSC57777.2023.10422618
M3 - Conference contribution
AN - SCOPUS:85186503217
T3 - IEEE Conference on Intelligent Transportation Systems, Proceedings, ITSC
SP - 1474
EP - 1479
BT - 2023 IEEE 26th International Conference on Intelligent Transportation Systems, ITSC 2023
PB - Institute of Electrical and Electronics Engineers
Y2 - 24 September 2023 through 28 September 2023
ER -