Quantized Control under Round-Robin Communication Protocol

Kun Liu; Emilia Fridman; Karl Henrik Johansson; Yuanqing Xia

doi:10.1109/TIE.2016.2539259

Quantized Control under Round-Robin Communication Protocol

Kun Liu, Emilia Fridman, Karl Henrik Johansson, Yuanqing Xia

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81 引用（Scopus）

摘要

This paper analyzes the exponential stability of a discrete-time linear plant in feedback control over a communication network with $N$ sensor nodes, dynamic quantization, large communication delays, variable sampling intervals, and round-robin scheduling. The closed-loop system is modeled as a switched system with multiple-ordered time-varying delays and bounded disturbances. We propose a time-triggered zooming algorithm implemented at the sensors that preserves exponential stability of the closed-loop system. A direct Lyapunov approach is presented for initialization of the zoom variable. The proposed framework can be applied to the plants with polytopic type uncertainties. The effectiveness of the method is illustrated on cart-pendulum and quadruple-tank processes.

源语言	英语
文章编号	7428903
页（从-至）	4461-4471
页数	11
期刊	IEEE Transactions on Industrial Electronics
卷	63
期	7
DOI	https://doi.org/10.1109/TIE.2016.2539259
出版状态	已出版 - 7月 2016

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title = "Quantized Control under Round-Robin Communication Protocol",

abstract = "This paper analyzes the exponential stability of a discrete-time linear plant in feedback control over a communication network with $N$ sensor nodes, dynamic quantization, large communication delays, variable sampling intervals, and round-robin scheduling. The closed-loop system is modeled as a switched system with multiple-ordered time-varying delays and bounded disturbances. We propose a time-triggered zooming algorithm implemented at the sensors that preserves exponential stability of the closed-loop system. A direct Lyapunov approach is presented for initialization of the zoom variable. The proposed framework can be applied to the plants with polytopic type uncertainties. The effectiveness of the method is illustrated on cart-pendulum and quadruple-tank processes.",

keywords = "Lyapunov method, Networked control systems, Round-Robin protocol, dynamic quantization, switched time-delay systems",

author = "Kun Liu and Emilia Fridman and Johansson, {Karl Henrik} and Yuanqing Xia",

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AB - This paper analyzes the exponential stability of a discrete-time linear plant in feedback control over a communication network with $N$ sensor nodes, dynamic quantization, large communication delays, variable sampling intervals, and round-robin scheduling. The closed-loop system is modeled as a switched system with multiple-ordered time-varying delays and bounded disturbances. We propose a time-triggered zooming algorithm implemented at the sensors that preserves exponential stability of the closed-loop system. A direct Lyapunov approach is presented for initialization of the zoom variable. The proposed framework can be applied to the plants with polytopic type uncertainties. The effectiveness of the method is illustrated on cart-pendulum and quadruple-tank processes.

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Quantized Control under Round-Robin Communication Protocol

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