Synchronization of Fractional Reaction-Diffusion Complex Networks With Unknown Couplings

Mouquan Shen; Chen Wang; Qing Guo Wang; Yonghui Sun; Guangdeng Zong

doi:10.1109/TNSE.2024.3432997

Synchronization of Fractional Reaction-Diffusion Complex Networks With Unknown Couplings

Mouquan Shen, Chen Wang, Qing Guo Wang, Yonghui Sun, Guangdeng Zong

COLLEGE OF ELECTRICAL ENGINEERING AND CONTROL SCIENCE

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

This paper delves into the synchronization of factional uncertain reaction-diffusion complex network. An adaptive scheme composed of time t and space x is utilized to handle unknown couplings. An output-strict passivity lemma is established by means of Green theorem, Kronecker product and the Lyapunov stability theorem. Different from classical synchronous approaches by constructing controllers, a criterion in terms of linear matrix inequality is built on the passivity lemma, Laplace transform and inverse transform to make the resultant closed-loop system be synchronization. Two examples are provided to validate the validity of the proposed methods.

Original language	English
Pages (from-to)	4503-4512
Number of pages	10
Journal	IEEE Transactions on Network Science and Engineering
Volume	11
Issue number	5
DOIs	https://doi.org/10.1109/TNSE.2024.3432997
State	Published - 2024

Keywords

Complex network
fractional reaction-diffusion system
linear matrix inequality
synchronization

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title = "Synchronization of Fractional Reaction-Diffusion Complex Networks With Unknown Couplings",

abstract = "This paper delves into the synchronization of factional uncertain reaction-diffusion complex network. An adaptive scheme composed of time t and space x is utilized to handle unknown couplings. An output-strict passivity lemma is established by means of Green theorem, Kronecker product and the Lyapunov stability theorem. Different from classical synchronous approaches by constructing controllers, a criterion in terms of linear matrix inequality is built on the passivity lemma, Laplace transform and inverse transform to make the resultant closed-loop system be synchronization. Two examples are provided to validate the validity of the proposed methods.",

keywords = "Complex network, fractional reaction-diffusion system, linear matrix inequality, synchronization",

author = "Mouquan Shen and Chen Wang and Wang, {Qing Guo} and Yonghui Sun and Guangdeng Zong",

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AU - Shen, Mouquan

AU - Wang, Chen

AU - Wang, Qing Guo

AU - Sun, Yonghui

AU - Zong, Guangdeng

PY - 2024

Y1 - 2024

N2 - This paper delves into the synchronization of factional uncertain reaction-diffusion complex network. An adaptive scheme composed of time t and space x is utilized to handle unknown couplings. An output-strict passivity lemma is established by means of Green theorem, Kronecker product and the Lyapunov stability theorem. Different from classical synchronous approaches by constructing controllers, a criterion in terms of linear matrix inequality is built on the passivity lemma, Laplace transform and inverse transform to make the resultant closed-loop system be synchronization. Two examples are provided to validate the validity of the proposed methods.

AB - This paper delves into the synchronization of factional uncertain reaction-diffusion complex network. An adaptive scheme composed of time t and space x is utilized to handle unknown couplings. An output-strict passivity lemma is established by means of Green theorem, Kronecker product and the Lyapunov stability theorem. Different from classical synchronous approaches by constructing controllers, a criterion in terms of linear matrix inequality is built on the passivity lemma, Laplace transform and inverse transform to make the resultant closed-loop system be synchronization. Two examples are provided to validate the validity of the proposed methods.

KW - Complex network

KW - fractional reaction-diffusion system

KW - linear matrix inequality

KW - synchronization

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EP - 4512

JO - IEEE Transactions on Network Science and Engineering

JF - IEEE Transactions on Network Science and Engineering

IS - 5

ER -

Synchronization of Fractional Reaction-Diffusion Complex Networks With Unknown Couplings

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