Qingchen Liu scite author profile

This paper proposes three different distributed event-triggered control algorithms to achieve leader-follower consensus for a network of Euler-Lagrange agents. We firstly propose two model-independent algorithms for a subclass of Euler-Lagrange agents without the vector of gravitational potential forces. By model-independent, we mean that each agent can execute its algorithm with no knowledge of the agent selfdynamics. A variable-gain algorithm is employed when the sensing graph is undirected; algorithm parameters are selected in a fully distributed manner with much greater flexibility compared to all previous work concerning event-triggered consensus problems. When the sensing graph is directed, a constant-gain algorithm is employed. The control gains must be centrally designed to exceed several lower bounding inequalities which require limited knowledge of bounds on the matrices describing the agent dynamics, bounds on network topology information and bounds on the initial conditions. When the Euler-Lagrange agents have dynamics which include the vector of gravitational potential forces, an adaptive algorithm is proposed which requires more information about the agent dynamics but can estimate uncertain agent parameters.For each algorithm, a trigger function is proposed to govern the event update times. At each event, the controller is updated, which ensures that the control input is piecewise constant and saves energy resources. We analyse each controllers and trigger function and exclude Zeno behaviour. Extensive simulations show 1) the advantages of our proposed trigger function as compared to those in existing literature, and 2) the effectiveness of our proposed controllers.

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Circular Formation Algorithms for Multiple Nonholonomic Mobile Robots: An Optimization-Based Approach

Qin

Wang

Kang

et al. 2019

IEEE Trans. Ind. Electron.

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Generalized controllers for rigid formation stabilization with application to event-based controller design

Sun

Liu

et al. 2015

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This paper discusses generalized controllers for rigid formation shape stabilization. We provide unified analysis to show convergence using different controllers reported in the literature, and further prove an exponential stability of the formation system when using the general form of shape controllers. We also show that different agents can use different controllers for controlling different distances to achieve a desired rigid formation, which enables the implementation of heterogeneous agents in practice for formation shape control. We further propose an event-triggered rigid formation control scheme based on the generalized controllers. The triggering condition, event function and convergence analysis are discussed.

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Qingchen Liu

SiO2 nanoparticles induce global genomic hypomethylation in HaCaT cells

Investigation on the binding site in heparin by spectrophotometry

Event-Triggered Algorithms for Leader–Follower Consensus of Networked Euler–Lagrange Agents

Circular Formation Algorithms for Multiple Nonholonomic Mobile Robots: An Optimization-Based Approach

Generalized controllers for rigid formation stabilization with application to event-based controller design

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