Litcius/Paper detail

Fault-Tolerant Synchronization for Memristive Neural Networks With Multiple Actuator Failures

Mingxin Wang, Song Zhu, Mouquan Shen, Xiaoyang Liu, Shiping Wen

2024IEEE Transactions on Cybernetics36 citationsDOI

Abstract

By using the fault-tolerant control method, the synchronization of memristive neural networks (MNNs) subjected to multiple actuator failures is investigated in this article. The considered actuator failures include the effectiveness failure and the lock-in-place failure, which are different from previous results. First of all, the mathematical expression of the control inputs in the considered system is given by introducing the models of the above two types of actuator failures. Following, two classes of synchronization strategies, which are state feedback control strategies and event-triggered control strategies, are proposed by using some inequality techniques and Lyapunov stability theories. The designed controllers can, respectively, guarantee the realization of synchronizations of the global exponential, the finite-time and the fixed-time for the MNNs by selecting different parameter conditions. Then the estimations of settling times of provided synchronization schemes are computed and the Zeno phenomenon of proposed event-triggered strategies is explicitly excluded. Finally, two experiments are conducted to confirm the availability of given synchronization strategies.

Topics & Concepts

Control theory (sociology)Synchronization (alternating current)Computer scienceActuatorSettling timeLyapunov stabilityRealization (probability)Artificial neural networkFault toleranceController (irrigation)Fault (geology)Control engineeringControl (management)Distributed computingMathematicsArtificial intelligenceEngineeringChannel (broadcasting)SeismologyComputer networkAgronomyGeologyStep responseBiologyStatisticsNeural Networks Stability and Synchronizationstochastic dynamics and bifurcationAdvanced Memory and Neural Computing
Fault-Tolerant Synchronization for Memristive Neural Networks With Multiple Actuator Failures | Litcius