1551-3203 (c) 2016 IEEE. Personal use is permitted, but republication/redistribution requires IEEE permission. See http://www.ieee.org/publications_standards/publications/rights/index.html for more information.
This article has been accepted for publication in a future issue of this journal, but has not been fully edited. Content may change prior to final publication. Citation information: DOI 10.1109/TII.2016.2590302, IEEE
Transactions on Industrial Informatics
8
the FuzzyGroupLearming algorithm against the other three
algorithms in Table IV. The percentages in the table are
calculated based on the average values of correspoinding
metrics in different traffic levels and traffic patterns.
VI.
C
ONCLUSION AND
F
UTURE
W
ORK
In this paper, we study the intersection control problem for
smart transportation systems in smart cities. Different from
existing works, we propose to divide the waiting vehicles in a
lane into different groups. The permission of passing
intersection is then granted in terms of vehicle groups, via V2I
communications. The major challenge lies in determining the
appropriate groups based on real-time traffic conditions, with
respect to requirements of average waiting time and fairness.
We adopt neuro-fuzzy network to do the grouping and also the
group scheduling. Furthermore, we apply reinforcement
learning to fine-tuning the parameters of the network and make
it adaptive to various traffic conditions. Grouping vehicles
makes our intersection control algorithm efficient and fair,
especially in high dynamic traffic flows. Such advantages have
been validated via extensive simulations.
Group based intersection control is a novel approach and
more efforts need to be made for better solutions. Possible
directions include improving the grouping fuzzy rules with
other machine learning techniques, considering more complex
scenarios of multiple intersections.
R
EFERENCES
[1]
Berenji H. R., Khedkar P. Learning and tuning fuzzy logic controllers
through reinforcements. Neural Networks, IEEE Transactions on, 1992,
3(5): 724-740.
[2]
Bingham E. Reinforcement learning in neurofuzzy traffic signal control.
European Journal of Operational Research, 2001, 131(2): 232-241.
[3]
Cai C., Wang Y., Geers G. Adaptive traffic signal control using vehicle-
to-infrastructure communication: a technical note[C]. Proceedings of the
Second International Workshop on Computational Transportation
Science. ACM, 2010: 43-47.
[4]
Chan K. Y., Khadem S., Dillon, T. S., Palade, V. Selection of Significant
On-Road Sensor Data for Short-Term Traffic Flow Forecasting Using the
Taguchi Method. Industrial Informatics, IEEE Transactions on, 8(2): 255
– 266, May 2012.
[5]
Dresner K., Stone P. Multiagent traffic management: A reservation-based
intersection control mechanism, Proceedings of the Third International
Joint Conference on Autonomous Agents and Multiagent Systems-
Volume 2. IEEE Computer Society, 2004: 530-537.
[6]
Dresner K. M., Stone P. A. Multiagent Approach to Autonomous
Intersection Management. J. Artif. Intell. Res.(JAIR), 2008, 31: 591-656.
[7]
Ferreira M., Fernandes R., Conceição H, et al. Self-organized traffic
control[C]. Proceedings of the seventh ACM international workshop on
VehiculAr InterNETworking. ACM, 2010: 85-90.
[8]
Ferreira M., d'Orey P. M. On the impact of virtual traffic lights on carbon
emissions mitigation. Intelligent Transportation Systems, IEEE
Transactions on, 2012, 13(1): 284-295.
[9]
Gokulan B. P., Srinivasan D. Distributed geometric fuzzy multiagent
urban traffic signal control. Intelligent Transportation Systems, IEEE
Transactions on, 2010, 11(3): 714-727.
[10]
Glaser S., Vanholme B., Mammar S, et al. Maneuver-based trajectory
planning for highly autonomous vehicles on real road with traffic and
driver interaction. Intelligent Transportation Systems, IEEE Transactions
on, 2010, 11(3): 589-606.
[11]
Gradinescu V., Gorgorin C., Diaconescu R, et al. Adaptive traffic lights
using car-to-car communication[C]. Vehicular Technology Conference,
2007. VTC2007-Spring. IEEE 65th. IEEE, 2007: 21-25.
[12]
Hartenstein H., Laberteaux K. P. A tutorial survey on vehicular ad hoc
networks. Communications Magazine, IEEE, 2008, 46(6): 164-171.
[13]
Hunt P. B., Robertson D I, Bretherton R D, et al. The SCOOT on-line
traffic signal optimisation technique. Traffic Engineering & Control, 1982,
23(4).
[14]
Lee J., Park B. Development and evaluation of a cooperative vehicle
intersection control algorithm under the connected vehicles environment.
Intelligent Transportation Systems, IEEE Transactions on, 2012, 13(1):
81-90.
[15]
Lertworawanich P., Kuwahara M., Miska M. A new multiobjective signal
optimization for oversaturated networks. Intelligent Transportation
Systems, IEEE Transactions on, 2011, 12(4): 967-976.
[16]
Li C., Shimamoto S. An Open Traffic Light Control Model for Reducing
Vehicles' Emissions Based on ETC Vehicles. Vehicular Technology,
IEEE Transactions on, 2012, 61(1): 97-110.
[17]
Lin C. T., Lee C. S. G.. Neural-network-based fuzzy logic control and
decision system. Computers, IEEE Transactions on, 1991, 40(12): 1320-
1336.
[18]
Lin C. T., Lee C. S. G. Reinforcement structure/parameter learning for
neural-network-based fuzzy logic control systems. Fuzzy Systems, IEEE
Transactions on, 1994, 2(1): 46-63.
[19]
Lin W. H., Wang C. An enhanced 0-1 mixed-integer LP formulation for
traffic signal control. Intelligent Transportation Systems, IEEE
Transactions on, 2004, 5(4): 238-245.
[20]
Maslekar N., Boussedjra M., Mouzna J., et al. VANET based adaptive
traffic signal control, Vehicular Technology Conference (VTC Spring),
2011 IEEE 73rd. IEEE, 2011: 1-5.
[21]
Milanés V., Pérez J., Onieva E., et al. Controller for urban intersections
based on wireless communications and fuzzy logic. Intelligent
Transportation Systems, IEEE Transactions on, 2010, 11(1): 243-248.
[22]
Milanés V., Villagra J., Godoy J., et al. An intelligent V2I-based traffic
management system. Intelligent Transportation Systems, IEEE
Transactions on, 2012, 13(1): 49-58.
[23]
Prashanth L. A., Bhatnagar S. Reinforcement learning with function
approximation for traffic signal control. Intelligent Transportation
Systems, IEEE Transactions on, 2011, 12(2): 412-421.
[24]
Priemer C., Friedrich B. A decentralized adaptive traffic signal control
using V2I communication data, Intelligent Transportation Systems, 2009.
ITSC'09. 12th International IEEE Conference on. IEEE, 2009: 1-6.
[25]
Qiao J., Yang N., Gao J. Two-stage fuzzy logic controller for signalized
intersection. Systems, Man and Cybernetics, Part A: Systems and Humans,
IEEE Transactions on, 2011, 41(1): 178-184.
[26]
Sims A. G., Dobinson K. W. The Sydney coordinated adaptive traffic
(SCAT) system philosophy and benefits. Vehicular Technology, IEEE
Transactions on, 1980, 29(2): 130-137.
[27]
Srinivasan D., Choy M. C., Cheu R. L. Neural networks for real-time
traffic signal control. Intelligent Transportation Systems, IEEE
Transactions on, 2006, 7(3): 261-272.
[28]
Vasirani M., Ossowski S. A computational market for distributed control
of urban road traffic systems. Intelligent Transportation Systems, IEEE
Transactions on, 2011, 12(2): 313-321.
[29]
Wang F. Y. Parallel control and management for intelligent transportation
systems:
Concepts,
architectures,
and
applications.
Intelligent
Transportation Systems, IEEE Transactions on, 2010, 11(3): 630-638.
[30]
Wu H., Yan G., Xu L. D. Developing Vehicular Data Cloud Services in
the IoT Environment, Industrial Informatics, IEEE Transactions on, 10(2):
1587 – 1595, May 2014.
[31]
Wu W., Zhang J., Luo A., Cao J. Distributed Mutual Exclusion
Algorithms for Intersection Traffic Control, Parallel and Distributed
Systems, IEEE Transactions on, 2015, Jan., 26(1): 65-74.
[32]
Wunderlich R., Liu C., Elhanany I., et al. A novel signal-scheduling
algorithm with quality-of-service provisioning for an isolated intersection.
Intelligent Transportation Systems, IEEE Transactions on, 2008, 9(3):
536-547.
[33]
Zhang G., Wang Y. Optimizing minimum and maximum green time
settings for traffic actuated control at isolated intersections. Intelligent
Transportation Systems, IEEE Transactions on, 2011, 12(1): 164-173.
[34]
Zhao D., Dai Y. Zhang Z. Computational intelligence in urban traffic
signal control: a survey. Systems, Man, and Cybernetics, Part C:
Applications and Reviews, IEEE Transactions on, 2012, 42(4): 485-494.
[35]
Zhou B., Cao J., Zeng X., et al. Adaptive traffic light control in wireless
sensor network-based intelligent transportation system, Vehicular
Technology Conference Fall (VTC 2010-Fall), 2010 IEEE 72nd. IEEE,
2010: 1-5.
Do'stlaringiz bilan baham: