Mixed-Triggered Reliable Control for Singular Networked Cascade Control Systems with Randomly Occurring Cyber Attack
For control engineers, this work addresses security and resource efficiency in singular NCCSs, but the results are incremental as they extend existing mixed-triggered and dissipative control frameworks to a specific model.
This paper proposes a mixed-triggered reliable control scheme for singular networked cascade control systems (NCCSs) under actuator saturation and randomly occurring cyber attacks, achieving admissibility and strict dissipativity. A numerical example on a boiler-turbine system validates the approach.
In this paper, the issue of mixed-triggered reliable dissipative control is investigated for singular networked cascade control systems (NCCSs) with actuator saturation and randomly occurring cyber attacks. In order to utilize the limited communication resources effectively, a more general mixed-triggered scheme is established which includes both schemes namely time-triggered and event-triggered in a single framework. In particular, two main factors are incorporated to the proposed singular NCCS model namely, actuator saturation and randomly occurring cyber attack, which is an important role to damage the overall network security. By employing Lyapunov-Krasovskii stability theory, a new set of sufficient conditions in terms of linear matrix inequalities (LMIs) is derived to guarantee the singular NCCSs to be admissible and strictly (Q,S,R)-dissipative. Subsequently, a power plant boiler-turbine system based on a numerical example is provided to demonstrate the effectiveness of the proposed control scheme.