Variable-time impulsive control for bipartite synchronization of coupled complex networks with signed graphs

•The communication topology can be either collaborative or antagonistic.•The appearance of impulses is dependent on each node in the complex networks.•The error nodes intersect every impulsive surface Υl exactly once.•Obtain the relationship of new jump operation between VTISs and FTISs.•Formulate t...

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Bibliographic Details
Published in:Applied mathematics and computation 2022-05, Vol.420, p.126899, Article 126899
Main Authors: Yang, Shiju, Li, Chuandong, He, Xiping, Zhang, Wanli
Format: Article
Language:English
Subjects:
Bipartite synchronization
Coupled complex networks
Signed graphs
Variable-time impulsive control
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Summary:•The communication topology can be either collaborative or antagonistic.•The appearance of impulses is dependent on each node in the complex networks.•The error nodes intersect every impulsive surface Υl exactly once.•Obtain the relationship of new jump operation between VTISs and FTISs.•Formulate the theoretical framework of bipartite synchronization criterion. This paper investigates the bipartite synchronization of coupled complex networks (CCNs) with signed graphs via variable-time impulsive (VTI) control. Different from the traditional complex networks, the communication topology between nodes of the complex networks can be either collaborative or antagonistic. In addition, the appearance of impulses is always dependent on each node in the network instead of appearing at fixed instants. Furthermore, by utilizing the B-equivalent technique, the VTI network models can be changed as fixed-time impulsive CCNs. The fixed-time impulsively controlled CCNs can be regarded as the comparison systems of the signed CCNs with variable-time impulses. By 1-norm analytical techniques, several assumptions are derived to guarantee every solution of the coupled error nodes intersect each discontinuous impulsive surface exactly once. Some sufficient conditions with theoretical demonstration are presented to guarantee the bipartite synchronization under mathematical induction. Simulation results are carried out to show the effectiveness of the obtained results.
ISSN:0096-3003
1873-5649
DOI:10.1016/j.amc.2021.126899