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Event-based adaptive neural resilient formation control for MIMO nonlinear MASs under actuator saturation and denial-of-service attacks

Xiangjun Wu, Ning Xu, Shuo Ding, Xudong Zhao, Ben Niu, Wencheng Wang, Xudong Zhao, Ben Niu, Ben Niu, Wencheng Wang, Wencheng Wang

2024Information Sciences32 citationsDOIOpen Access PDF

Abstract

This paper focuses on the distributed event-triggered adaptive neural resilient time-varying formation control problem for a class of multiple-input multiple-output nonlinear multi-agent systems, where all network communication links between agents are subjected to denial-of-service (DoS) attacks simultaneously. A second-order resilient time-varying formation estimator is designed to obtain the unknown leader information in DoS attack active intervals. Meanwhile, a state-triggering mechanism (STM) is designed to save system communication resources. Nevertheless, the STM can lead to virtual control laws being non-differentiable. To circumvent the problem, we first design an adaptive neural resilient formation control scheme. Then, based on the adaptive neural resilient formation control scheme, we replace continuous states with intermittent ones. By utilizing a dynamic filtering technique, an event-based adaptive neural resilient formation control scheme is designed. The key technology of control scheme design is to establish an improved first-order auxiliary system to deal with the negative impact of actuator saturation. It is proved that formation tracking errors can converge to a residual set around zero, and all signals in the closed-loop system are semi-globally uniformly ultimately bounded. Finally, simulation results are presented to show the effectiveness of the control scheme.

Topics & Concepts

Denial-of-service attackControl theory (sociology)Nonlinear systemSaturation (graph theory)Event (particle physics)ActuatorComputer scienceControl (management)PhysicsMathematicsArtificial intelligenceCombinatoricsWorld Wide WebQuantum mechanicsThe InternetDistributed Control Multi-Agent SystemsNeural Networks Stability and SynchronizationAdaptive Control of Nonlinear Systems