Optimal Control of Connected Vehicle Systems With Communication Delay and Driver Reaction Time

In this paper, linear quadratic regulation is used to obtain an optimal design of connected cruise control (CCC). We consider vehicle strings where a CCC vehicle receives position and velocity signals through wireless vehicle-to-vehicle communication from multiple vehicles ahead. Communication delay...

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Bibliographic Details
Published in:IEEE transactions on intelligent transportation systems Vol. 18; no. 8; pp. 2056 - 2070
Main Authors: Ge, Jin I., Orosz, Gabor
Format: Journal Article
Language:English
Published: New York IEEE 01.08.2017
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Acceleration
Automobiles
Automotive engineering
Communication
Computational modeling
Computer simulation
Connected vehicles
Cost engineering
Cost function
Cruise control
Delay
delay systems
Delays
Driver response time
Feedback
Heterogeneity
Laws
Linear quadratic regulator
Optimal control
Optimization
Robustness (mathematics)
Strings
Vehicles
Velocity errors
Wireless communications
ISSN:1524-9050, 1558-0016
Online Access:Get full text
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Summary:In this paper, linear quadratic regulation is used to obtain an optimal design of connected cruise control (CCC). We consider vehicle strings where a CCC vehicle receives position and velocity signals through wireless vehicle-to-vehicle communication from multiple vehicles ahead. Communication delay, driver reaction time, and heterogeneity of vehicles are considered. The optimal feedback law is obtained by minimizing a cost function defined by headway and velocity errors and the acceleration of the CCC vehicle on an infinite horizon. We show that, by decomposing the optimization problem, the feedback gains can be obtained recursively as signals from vehicles farther ahead become available, and that the gains decay exponentially with the number of cars between the source of the signal and the CCC vehicle. Such properties allow graceful degradation of CCC performance under imperfect communication. The effects of the cost function on the head-to-tail string stability are also investigated and the robustness against variations in human parameters is tested. The analytical results are verified by numerical simulations at the nonlinear level. The results allow us to significantly reduce the complexity of CCC design.
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ISSN:1524-9050
1558-0016
DOI:10.1109/TITS.2016.2633164