Constrained optimization and distributed computation based car following control of a connected and autonomous vehicle platoon

•Systematic car-following control algorithm for a connected and autonomous vehicle platoon.•Distributed algorithm solving a convex optimization with coupled constraints.•Stability analysis to demonstrate the desired transient and asymptotic dynamics. Motivated by the advancement in connected and aut...

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Published inTransportation research. Part B: methodological Vol. 94; pp. 314 - 334
Main Authors Gong, Siyuan, Shen, Jinglai, Du, Lili
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.12.2016
Elsevier Science Ltd
Subjects
Algorithms
Asymptotic properties
Automobiles
Automotive engineering
Autonomous cars
Autonomous vehicles
Car following
Car-following control
Computer simulation
Connected and autonomous vehicles
Constraints
Distributed algorithm
Dynamical systems
Dynamics
Environmental impact
Mathematical models
Multiagent systems
Optimization
Smoothness
Stability analysis
Sustainable development
Traffic congestion
Connected and autonomous vehicles
Car-following control
Optimization
Distributed algorithm
Online AccessGet full text
ISSN0191-2615
1879-2367
DOI10.1016/j.trb.2016.09.016

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Abstract •Systematic car-following control algorithm for a connected and autonomous vehicle platoon.•Distributed algorithm solving a convex optimization with coupled constraints.•Stability analysis to demonstrate the desired transient and asymptotic dynamics. Motivated by the advancement in connected and autonomous vehicle technologies, this paper develops a novel car-following control scheme for a platoon of connected and autonomous vehicles on a straight highway. The platoon is modeled as an interconnected multi-agent dynamical system subject to physical and safety constraints, and it uses the global information structure such that each vehicle shares information with all the other vehicles. A constrained optimization based control scheme is proposed to ensure an entire platoon’s transient traffic smoothness and asymptotic dynamic performance. By exploiting the solution properties of the underlying optimization problem and using primal-dual formulation, this paper develops dual based distributed algorithms to compute optimal solutions with proven convergence. Furthermore, the asymptotic stability of the unconstrained linear closed-loop system is established. These stability analysis results provide a principle to select penalty weights in the underlying optimization problem to achieve the desired closed-loop performance for both the transient and the asymptotic dynamics. Extensive numerical simulations are conducted to validate the efficiency of the proposed algorithms.
AbstractList Motivated by the advancement in connected and autonomous vehicle technologies, this paper develops a novel car-following control scheme for a platoon of connected and autonomous vehicles on a straight highway. The platoon is modeled as an interconnected multi-agent dynamical system subject to physical and safety constraints, and it uses the global information structure such that each vehicle shares information with all the other vehicles. A constrained optimization based control scheme is proposed to ensure an entire platoon’s transient traffic smoothness and asymptotic dynamic performance. By exploiting the solution properties of the underlying optimization problem and using primal-dual formulation, this paper develops dual based distributed algorithms to compute optimal solutions with proven convergence. Furthermore, the asymptotic stability of the unconstrained linear closed-loop system is established. These stability analysis results provide a principle to select penalty weights in the underlying optimization problem to achieve the desired closed-loop performance for both the transient and the asymptotic dynamics. Extensive numerical simulations are conducted to validate the efficiency of the proposed algorithms.
•Systematic car-following control algorithm for a connected and autonomous vehicle platoon.•Distributed algorithm solving a convex optimization with coupled constraints.•Stability analysis to demonstrate the desired transient and asymptotic dynamics. Motivated by the advancement in connected and autonomous vehicle technologies, this paper develops a novel car-following control scheme for a platoon of connected and autonomous vehicles on a straight highway. The platoon is modeled as an interconnected multi-agent dynamical system subject to physical and safety constraints, and it uses the global information structure such that each vehicle shares information with all the other vehicles. A constrained optimization based control scheme is proposed to ensure an entire platoon’s transient traffic smoothness and asymptotic dynamic performance. By exploiting the solution properties of the underlying optimization problem and using primal-dual formulation, this paper develops dual based distributed algorithms to compute optimal solutions with proven convergence. Furthermore, the asymptotic stability of the unconstrained linear closed-loop system is established. These stability analysis results provide a principle to select penalty weights in the underlying optimization problem to achieve the desired closed-loop performance for both the transient and the asymptotic dynamics. Extensive numerical simulations are conducted to validate the efficiency of the proposed algorithms.
Author Shen, Jinglai
Du, Lili
Gong, Siyuan
Author_xml – sequence: 1
  givenname: Siyuan
  surname: Gong
  fullname: Gong, Siyuan
  email: sgong1@hawk.iit.edu
  organization: Department of Civil, Architectural and Environmental Engineering, Illinois Institute of Technology, Chicago, IL 60616, USA
– sequence: 2
  givenname: Jinglai
  surname: Shen
  fullname: Shen, Jinglai
  email: shenj@umbc.edu
  organization: Department of Mathematics and Statistics, University of Maryland Baltimore County, MD 21250, USA
– sequence: 3
  givenname: Lili
  surname: Du
  fullname: Du, Lili
  email: ldu3@iit.edu
  organization: Department of Civil, Architectural and Environmental Engineering, Illinois Institute of Technology, Chicago, IL 60616, USA
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Car-following control
Optimization
Distributed algorithm
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Snippet •Systematic car-following control algorithm for a connected and autonomous vehicle platoon.•Distributed algorithm solving a convex optimization with coupled...
Motivated by the advancement in connected and autonomous vehicle technologies, this paper develops a novel car-following control scheme for a platoon of...
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SubjectTerms Algorithms
Asymptotic properties
Automobiles
Automotive engineering
Autonomous cars
Autonomous vehicles
Car following
Car-following control
Computer simulation
Connected and autonomous vehicles
Constraints
Distributed algorithm
Dynamical systems
Dynamics
Environmental impact
Mathematical models
Multiagent systems
Optimization
Smoothness
Stability analysis
Sustainable development
Traffic congestion
Title Constrained optimization and distributed computation based car following control of a connected and autonomous vehicle platoon
URI https://dx.doi.org/10.1016/j.trb.2016.09.016
https://www.proquest.com/docview/2077576936
https://www.proquest.com/docview/1850781193
https://www.proquest.com/docview/1864575238
Volume 94
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