Disturbance rejection for multi-weighted complex dynamical networks with actuator saturation and deception attacks via hybrid-triggered mechanism

R. Sakthivel; O. M. Kwon; M. J. Park; S. M. Lee

doi:10.1016/j.neunet.2023.02.031

Disturbance rejection for multi-weighted complex dynamical networks with actuator saturation and deception attacks via hybrid-triggered mechanism

R. Sakthivel, O. M. Kwon, M. J. Park, S. M. Lee

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

12 Scopus citations

Abstract

In this work, we address hybrid-driven-based robust synchronization problem for multi-weighted complex dynamical networks with actuator saturation and deception attacks. The hybrid-triggered mechanism, which combines a switch between the event-triggered scheme and the time-triggered scheme, is often used to reduce the data transmission and the alleviate network burden. Further, the equivalent-input-disturbance technique is applied to eliminate the unknown disturbance effect of the addressed system. Moreover, a memory controller is designed under actuator saturation to ensure that the resultant augmented system is asymptotically synchronized even in the presence of deception attacks. Finally, three numerical examples are given to show the validity of the obtained theoretical results.

Original language	English
Pages (from-to)	225-239
Number of pages	15
Journal	Neural Networks
Volume	162
DOIs	https://doi.org/10.1016/j.neunet.2023.02.031
State	Published - May 2023

Keywords

Actuator saturation
Complex dynamical networks
Deception attacks
Equivalent-input-disturbance
Multi-weights

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10.1016/j.neunet.2023.02.031

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title = "Disturbance rejection for multi-weighted complex dynamical networks with actuator saturation and deception attacks via hybrid-triggered mechanism",

abstract = "In this work, we address hybrid-driven-based robust synchronization problem for multi-weighted complex dynamical networks with actuator saturation and deception attacks. The hybrid-triggered mechanism, which combines a switch between the event-triggered scheme and the time-triggered scheme, is often used to reduce the data transmission and the alleviate network burden. Further, the equivalent-input-disturbance technique is applied to eliminate the unknown disturbance effect of the addressed system. Moreover, a memory controller is designed under actuator saturation to ensure that the resultant augmented system is asymptotically synchronized even in the presence of deception attacks. Finally, three numerical examples are given to show the validity of the obtained theoretical results.",

keywords = "Actuator saturation, Complex dynamical networks, Deception attacks, Equivalent-input-disturbance, Multi-weights",

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AU - Sakthivel, R.

AU - Kwon, O. M.

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AU - Lee, S. M.

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AB - In this work, we address hybrid-driven-based robust synchronization problem for multi-weighted complex dynamical networks with actuator saturation and deception attacks. The hybrid-triggered mechanism, which combines a switch between the event-triggered scheme and the time-triggered scheme, is often used to reduce the data transmission and the alleviate network burden. Further, the equivalent-input-disturbance technique is applied to eliminate the unknown disturbance effect of the addressed system. Moreover, a memory controller is designed under actuator saturation to ensure that the resultant augmented system is asymptotically synchronized even in the presence of deception attacks. Finally, three numerical examples are given to show the validity of the obtained theoretical results.

KW - Actuator saturation

KW - Complex dynamical networks

KW - Deception attacks

KW - Equivalent-input-disturbance

KW - Multi-weights

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JO - Neural Networks

JF - Neural Networks

ER -

Disturbance rejection for multi-weighted complex dynamical networks with actuator saturation and deception attacks via hybrid-triggered mechanism

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