Finite-time consensus has attracted significant research interest due to its wide applications in multiagent systems. Various results have been developed to enable multiagent systems to complete desired tasks in finite-time. However, most existing results in the literature can only ensure finite-time consensus without considering temporal constraints, where the time used to achieve consensus cannot be preset arbitrarily and is generally determined by the system initial conditions, prohibiting its application in time-sensitive tasks. Motivated to achieve consensus within a desired time frame, user-specified finite-time consensus is developed in the present work for a multiagent system to ensure consensus at a prespecified time instant. The interaction among agents (e.g., communication and information exchange) is modeled as a time-varying graph, where each edge is associated with a time-varying weight representing the time-varying interaction between neighboring agents. Consensus over such time-varying graph is then proven based on a time transformation and is guaranteed to be completed within a prespecified time frame. To demonstrate the developed framework, finite-time rendezvous of a multiagent system is considered as an example application, where agents with limited communication capabilities are desired to meet at a common location at a preset time instant with constraints on preserving global network connectivity. A numerical simulation is provided to demonstrate the efficiency of the developed result.
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July 2017
Research-Article
A Finite-Time Consensus Framework Over Time-Varying Graph Topologies With Temporal Constraints
Zhen Kan,
Zhen Kan
Department of Mechanical and
Industrial Engineering,
The University of Iowa,
Iowa City, IA 52242
e-mail: zhen-kan@uiowa.edu
Industrial Engineering,
The University of Iowa,
Iowa City, IA 52242
e-mail: zhen-kan@uiowa.edu
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Tansel Yucelen,
Tansel Yucelen
Department of Mechanical Engineering,
University of South Florida,
Tampa, FL 33620
e-mail: yucelen@lacis.team
University of South Florida,
Tampa, FL 33620
e-mail: yucelen@lacis.team
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Emily Doucette,
Emily Doucette
Munitions Directorate,
Air Force Research Laboratory,
Eglin Air Force Base,
Shalimar, FL 32579
e-mail: emily.doucette@eglin.af.mil
Air Force Research Laboratory,
Eglin Air Force Base,
Shalimar, FL 32579
e-mail: emily.doucette@eglin.af.mil
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Eduardo Pasiliao
Eduardo Pasiliao
Munitions Directorate,
Air Force Research Laboratory,
Eglin Air Force Base,
Shalimar, FL 32579
e-mail: pasiliao@eglin.af.mil
Air Force Research Laboratory,
Eglin Air Force Base,
Shalimar, FL 32579
e-mail: pasiliao@eglin.af.mil
Search for other works by this author on:
Zhen Kan
Department of Mechanical and
Industrial Engineering,
The University of Iowa,
Iowa City, IA 52242
e-mail: zhen-kan@uiowa.edu
Industrial Engineering,
The University of Iowa,
Iowa City, IA 52242
e-mail: zhen-kan@uiowa.edu
Tansel Yucelen
Department of Mechanical Engineering,
University of South Florida,
Tampa, FL 33620
e-mail: yucelen@lacis.team
University of South Florida,
Tampa, FL 33620
e-mail: yucelen@lacis.team
Emily Doucette
Munitions Directorate,
Air Force Research Laboratory,
Eglin Air Force Base,
Shalimar, FL 32579
e-mail: emily.doucette@eglin.af.mil
Air Force Research Laboratory,
Eglin Air Force Base,
Shalimar, FL 32579
e-mail: emily.doucette@eglin.af.mil
Eduardo Pasiliao
Munitions Directorate,
Air Force Research Laboratory,
Eglin Air Force Base,
Shalimar, FL 32579
e-mail: pasiliao@eglin.af.mil
Air Force Research Laboratory,
Eglin Air Force Base,
Shalimar, FL 32579
e-mail: pasiliao@eglin.af.mil
1Corresponding author.
2Z. Kan and T. Yucelen contributed equally to this research.
Contributed by the Dynamic Systems Division of ASME for publication in the JOURNAL OF DYNAMIC SYSTEMS, MEASUREMENT, AND CONTROL. Manuscript received August 17, 2016; final manuscript received December 19, 2016; published online May 12, 2017. Assoc. Editor: Zongxuan Sun.
J. Dyn. Sys., Meas., Control. Jul 2017, 139(7): 071012 (6 pages)
Published Online: May 12, 2017
Article history
Received:
August 17, 2016
Revised:
December 19, 2016
Citation
Kan, Z., Yucelen, T., Doucette, E., and Pasiliao, E. (May 12, 2017). "A Finite-Time Consensus Framework Over Time-Varying Graph Topologies With Temporal Constraints." ASME. J. Dyn. Sys., Meas., Control. July 2017; 139(7): 071012. https://doi.org/10.1115/1.4035612
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