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Traffic Signal Control and Speed Offset Coordination Using Q-Learning for Arterial Road Networks (2404.06382v1)

Published 9 Apr 2024 in eess.SY and cs.SY

Abstract: Arterial traffic interacts with freeway traffic, yet the two are controlled independently. Arterial traffic signals do not take into account freeway traffic and how ramps control ingress traffic and have no control over egress traffic from the freeway. This often results in long queues in either direction that block ramps and spill over to arterial streets or freeway lanes. In this paper, we propose an adaptive arterial traffic control strategy that combines traffic signal control (TSC) and dynamic speed offset (DSO) coordination using a Q-learning algorithm for a traffic network that involves a freeway segment and adjacent arterial streets. The TSC agent computes the signal cycle length and split based on observed intersection demands and adjacent freeway off-ramp queues. The DSO agent computes the relative offset and the recommended speeds of both ways between consecutive intersections based on their physical distance, intersection queues, and signal cycles. We evaluate the performance of the proposed arterial traffic control strategy using microscopic traffic simulations of an arterial corridor with seven intersections near the I-710 freeway. The proposed QL-based control significantly outperforms a fixed-time control and MAXBAND in terms of the travel time and the number of stops under low or moderate demands. In high-demand scenarios, the travel-time benefit provided by the QL-based control is reduced as it mitigates off-ramp and intersection queues, which is a necessary trade-off in our perspective. In addition, mutual benefit is obtained by implementing freeway and arterial traffic control simultaneously.

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References (41)
  1. A review of the self-adaptive traffic signal control system based on future traffic environment. Journal of Advanced Transportation, 2018, 2018.
  2. A real-time adaptive signal control in a connected vehicle environment. Transportation Research Part C: Emerging Technologies, 55:460–473, 2015.
  3. A group-based traffic signal control with adaptive learning ability. Engineering applications of artificial intelligence, 65:282–293, 2017.
  4. Distributed signal control of arterial corridors using multi-agent deep reinforcement learning. IEEE Transactions on Intelligent Transportation Systems, 24(1):178–190, 2022.
  5. Interactive signal control for over-saturated arterial intersections using fuzzy logic. In 2008 11th International IEEE Conference on Intelligent Transportation Systems, pages 1067–1072. IEEE, 2008.
  6. Real-time incident-responsive signal control strategy under partially connected vehicle environment. Journal of Advanced Transportation, 2022, 2022.
  7. Hamdi Abdulkareem Mohammed Al-Nuaimi. The application of variable speed limits to arterial roads for improved traffic flow. PhD thesis, University of Southern Queensland, 2014.
  8. Speed advisory and signal offsets control for arterial bandwidth maximization and energy consumption reduction. IEEE Transactions on Control Systems Technology, 25(3):875–887, 2016.
  9. Eco-driving in urban traffic networks using traffic signals information. International Journal of Robust and Nonlinear Control, 26(6):1307–1324, 2016.
  10. Eco-approach and departure (ead) application for actuated signals in real-world traffic. IEEE Transactions on Intelligent Transportation Systems, 20(1):30–40, 2018.
  11. Eco-driving at signalized intersections: A multiple signal optimization approach. IEEE Transactions on Intelligent Transportation Systems, 22(5):2943–2955, 2020.
  12. Arterial traffic control using reinforcement learning agents and information from adjacent intersections in the state and reward structure. In 13th international IEEE conference on intelligent transportation systems, pages 525–530. IEEE, 2010.
  13. Integrated freeway and arterial traffic control to improve freeway mobility without compromising arterial traffic conditions using q-learning. arXiv preprint arXiv:2310.16748, 2023.
  14. Fo Vo Webster. Traffic signal settings. Technical report, 1958.
  15. Alan J Miller. Settings for fixed-cycle traffic signals. Journal of the Operational Research Society, 14(4):373–386, 1963.
  16. FV Webster. Traffic signals. Road research technical paper, 56, 1966.
  17. Computing optimum traffic signal cycle length considering vehicle delay and fuel consumption. Transportation Research Interdisciplinary Perspectives, 3:100021, 2019.
  18. Fred L Orcutt Jr. The traffic signal book. 1993.
  19. Maxband: A versatile program for setting signals on arteries and triangular networks. 1981.
  20. A multi-band approach to arterial traffic signal optimization. Transportation Research Part B: Methodological, 25(1):55–74, 1991.
  21. Arterial progression optimization using od-band: case study and extensions. Transportation Research Record, 2558(1):1–10, 2016.
  22. Dennis I Robertson. Transyt: a traffic network study tool. 1969.
  23. The scoot on-line traffic signal optimisation technique. Traffic Engineering & Control, 23(4), 1982.
  24. Rhodes to intelligent transportation systems. IEEE Intelligent Systems, 20(1):10–15, 2005.
  25. A survey on reinforcement learning models and algorithms for traffic signal control. ACM Computing Surveys (CSUR), 50(3):1–38, 2017.
  26. Multiagent reinforcement learning for urban traffic control using coordination graphs. In Machine Learning and Knowledge Discovery in Databases: European Conference, ECML PKDD 2008, Antwerp, Belgium, September 15-19, 2008, Proceedings, Part I 19, pages 656–671. Springer, 2008.
  27. Elise Van der Pol and Frans A Oliehoek. Coordinated deep reinforcement learners for traffic light control. Proceedings of learning, inference and control of multi-agent systems (at NIPS 2016), 8:21–38, 2016.
  28. Cooperative deep reinforcement learning for large-scale traffic grid signal control. IEEE transactions on cybernetics, 50(6):2687–2700, 2019.
  29. The traffic signal control problem for intersections: a review. European transport research review, 12:1–20, 2020.
  30. A rule-based real-time traffic responsive signal control system with transit priority: application to an isolated intersection. Transportation Research Part B: Methodological, 36(4):325–343, 2002.
  31. Development of dynamic transit signal priority strategy. Transportation research record, 2111(1):1–9, 2009.
  32. Real-time traffic signal control for isolated intersection, using car-following logic under connected vehicle environment. Transportation research procedia, 25:1610–1625, 2017.
  33. An enhanced 0-1 mixed-integer lp formulation for traffic signal control. IEEE Transactions on Intelligent transportation systems, 5(4):238–245, 2004.
  34. EN Barron and H Ishii. The bellman equation for minimizing the maximum cost. NONLINEAR ANAL. THEORY METHODS APPLIC., 13(9):1067–1090, 1989.
  35. Reinforcement learning: An introduction. MIT press, 2018.
  36. Deep learning. MIT press, 2016.
  37. Reinforcement learning-based variable speed limit control strategy to reduce traffic congestion at freeway recurrent bottlenecks. IEEE transactions on intelligent transportation systems, 18(11):3204–3217, 2017.
  38. Dhp method for ramp metering of freeway traffic. IEEE Transactions on Intelligent Transportation Systems, 12(4):990–999, 2011.
  39. Selection of the speed command distance for improved performance of a rule-based vsl and lane change control. IEEE Transactions on Intelligent Transportation Systems, 23(10):19348–19357, 2022.
  40. Combined variable speed limit and lane change control for highway traffic. IEEE Transactions on Intelligent Transportation Systems, 18(7):1812–1823, 2016.
  41. U Epa. Motor vehicle emission simulator (moves) user guide. US Environmental Protection Agency, 2010.

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