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Fault-Tolerant H-Infinity Stabilization for Networked Cascade Control Systems With Novel Adaptive Event-Triggered Mechanism

Zhaoping Du, Chen Chen, Changjiang Li, Xiaofei Yang, Jianzhen Li

2025IEEE Transactions on Automation Science and Engineering7 citationsDOI

Abstract

Networked cascade control systems (NCCS) are susceptible to performance degradation from network-induced delays, communication constraints, and component failures. To address these interconnected challenges, this paper develops an integrated fault-tolerant H-infinity control framework for discrete-time nonlinear NCCS. A key contribution is a novel, disturbance-aware adaptive event-triggered mechanism (AETM) that uniquely incorporates measurable external disturbances into its triggering logic. This design dynamically reduces communication frequency while preserving performance. Furthermore, a unified co-design of the controller parameters and the AETM’s weighting matrix is established, while stability is rigorously substantiated through theoretical analysis. Simulation results for a boiler control system validate the proposed method’s effectiveness, demonstrating significant improvements in both system robustness and communication efficiency.

Topics & Concepts

Control theory (sociology)CascadeRobustness (evolution)WeightingControl engineeringComputer scienceNonlinear systemAdaptive controlNetworked control systemControl systemRobust controlKey (lock)Adaptive systemEngineeringStability (learning theory)Component (thermodynamics)Telecommunications networkController (irrigation)Control reconfigurationControl (management)Communications systemInternal modelBandwidth (computing)Matrix algebraAdvanced Control Systems OptimizationControl and Stability of Dynamical SystemsStability and Control of Uncertain Systems
Fault-Tolerant H-Infinity Stabilization for Networked Cascade Control Systems With Novel Adaptive Event-Triggered Mechanism | Litcius