IgG4-related disease: Advances in the diagnosis and treatment

In this paper, the distributed formation control problem for multiple nonholonomic mobile robots using consensus-based approach is considered. A transformation is given to convert the formation control problem for multiple nonholonomic mobile robots into a state consensus problem. Distributed control laws are developed for achieving the formation control objectives: a group of nonholonomic mobile robots at least exponentially converge to a desired geometric pattern with its centroid moving along the specified reference trajectory. Rigorous proofs are provided by using graph, matrix , and Lyapunov theories. Simulations are also given to verify the effectiveness of the theoretical results.

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Adaptive distributed formation control for multiple nonholonomic wheeled mobile robots

Peng

Yang

Wen

et al. 2016

Neurocomputing

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Distributed consensus-based formation control for nonholonomic wheeled mobile robots using adaptive neural network

et al. 2016

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This paper investigates the distributed formation control problem for multiple nonholonomic wheeled mobile robots. A variable transformation is first proposed to convert the formation control problem into a state consensus problem. Then, when the dynamics of the mobile robots are considered, the distributed kinematic controllers and neural network torque controllers are derived for each robot such that a group of nonholonomic mobile robots asymptotically converge to a desired geometric pattern along the specified reference trajectory. The specified reference trajectory is assumed to be the trajectory of a virtual leader whose information is available to only a subset of the followers. Also the followers are assumed to have only local interaction. Moreover, the neural network torque controllers proposed in this work can tackle the dynamics of robots with unmodeled bounded disturbances and unstructured unmodeled dynamics. Some sufficient conditions are derived for accomplish the asymptotically stability of the systems based on algebraic graph theory, matrix theory, and Lyapunov control approach. Finally, simulation examples illustrate the effectiveness of the proposed controllers.

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Bond graph aided design of controlled systems

Dauphin-Tanguy

Rahmani

Sueur

1999

Simulation Practice and Theory

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Fully Distributed Formation-Containment Control of Heterogeneous Linear Multiagent Systems

Jiang

Wen

Peng

et al. 2019

IEEE Trans. Automat. Contr.

130

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Distributed leader-following consensus for second-order multi-agent systems with nonlinear inherent dynamics

Wen

Peng

Rahmani

et al. 2013

International Journal of Systems Science

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In this paper, the leader-following consensus problem for second-order multi-agent systems with nonlinear inherent dynamics is investigated. Two distributed control protocols are proposed under fixed undirected communication topology and fixed directed communication topology. Some sufficient conditions are obtained for the states of followers converging to the state of virtual leader globally exponentially. Rigorous proofs are given by using graph theory, matrix theory and Lyapunov theory. Simulations are also given to verify the effectiveness of the theoretical results.

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Distributed formation tracking of multi-robot systems with nonholonomic constraint via event-triggered approach

et al. 2018

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Ahmed Rahmani

Leader–follower formation control of nonholonomic mobile robots based on a bioinspired neurodynamic based approach

Distributed consensus-based formation control for multiple nonholonomic mobile robots with a specified reference trajectory

Adaptive distributed formation control for multiple nonholonomic wheeled mobile robots

Distributed consensus-based formation control for nonholonomic wheeled mobile robots using adaptive neural network

Bond graph aided design of controlled systems

Fully Distributed Formation-Containment Control of Heterogeneous Linear Multiagent Systems

Distributed leader-following consensus for second-order multi-agent systems with nonlinear inherent dynamics

Distributed formation tracking of multi-robot systems with nonholonomic constraint via event-triggered approach

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