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Resilient Asynchronous State Estimation for Markovian Jump Neural Networks Subject to Stochastic Nonlinearities and Sensor Saturations

Yong Xu, Zheng‐Guang Wu, Ya‐Jun Pan, Jian Sun

2021IEEE Transactions on Cybernetics34 citationsDOI

Abstract

This article studies the problem of dissipativity-based asynchronous state estimation for a class of discrete-time Markov jump neural networks subject to randomly occurring nonlinearities, sensor saturations, and stochastic parameter uncertainties. First, two stochastic nonlinearities occurring in the system are described by statistical means and obey two Bernoulli processes independently. Then, the hidden Markov model is used to characterize the real communication environment closely between the designed estimator and the system model due to the networked-induced phenomenons that also lead to randomly occurring parametric uncertainties of the estimator considered modeled by two Bernoulli processes. A new criterion is established to guarantee that the resulting error system is stochastically stable with predefined dissipativity performance. Finally, we provide a simulation example to validate the theoretical analysis.

Topics & Concepts

Bernoulli's principleComputer scienceControl theory (sociology)Asynchronous communicationEstimatorArtificial neural networkMarkov processJumpBernoulli distributionParametric statisticsState (computer science)Stochastic processHidden Markov modelState estimatorMathematicsAlgorithmRandom variableArtificial intelligenceEngineeringStatisticsControl (management)Aerospace engineeringPhysicsComputer networkQuantum mechanicsNeural Networks Stability and SynchronizationStability and Control of Uncertain SystemsAdvanced Memory and Neural Computing