Improving Deep Reinforcement Learning-Based Perimeter Metering Control Methods With Domain Control Knowledge
Perimeter metering control has long been an active research topic since well-defined relationships between network productivity and usage, that is, network macroscopic fundamental diagrams (MFDs), were shown to be capable of describing regional traffic dynamics. Numerous methods have been proposed to solve perimeter metering control problems, but these generally require knowledge of the MFDs or detailed equations that govern traffic dynamics. Recently, a study applied model-free deep reinforcement learning (Deep-RL) methods to two-region perimeter control and found comparable performances to the model predictive control scheme, particularly when uncertainty exists. However, the proposed methods therein provide very low initial performances during the learning process, which limits their applicability to real life scenarios. Furthermore, the methods may not be scalable to more complicated networks with larger state and action spaces. To combat these issues, this paper proposes to integrate the domain control knowledge (DCK) of congestion dynamics into the agent designs for improved learning and control performances. A novel agent is also developed that builds on the Bang-Bang control policy. Two types of DCK are then presented to provide knowledge-guided exploration strategies for the agents such that they can explore around the most rewarding part of the action spaces. The results from extensive numerical experiments on two- and three-region urban networks show that integrating DCK can (a) effectively improve learning and control performances for Deep-RL agents, (b) enhance the agents’ resilience against various types of environment uncertainties, and (c) mitigate the scalability issue for the agents.
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Availability:
- Find a library where document is available. Order URL: http://worldcat.org/issn/03611981
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Supplemental Notes:
- Vikash V. Gayah https://orcid.org/0000-0002-0648-3360© National Academy of Sciences: Transportation Research Board 2023.
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Authors:
- Zhou, Dongqin
- Gayah, Vikash V
- 0000-0002-0648-3360
- Publication Date: 2023-7
Language
- English
Media Info
- Media Type: Web
- Features: References;
- Pagination: pp 384-405
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Serial:
- Transportation Research Record: Journal of the Transportation Research Board
- Volume: 2677
- Issue Number: 7
- Publisher: Sage Publications, Incorporated
- ISSN: 0361-1981
- EISSN: 2169-4052
- Serial URL: http://journals.sagepub.com/home/trr
Subject/Index Terms
- TRT Terms: Knowledge; Machine learning; Predictive models; Traffic control
- Identifier Terms: Model Predictive Control
- Subject Areas: Highways; Operations and Traffic Management;
Filing Info
- Accession Number: 01873143
- Record Type: Publication
- Files: TRIS, TRB, ATRI
- Created Date: Feb 14 2023 12:00PM