Stabilization of delayed fractional‐order T‐S fuzzy systems with input saturations and system uncertainties

Abstract: By adopting the Takagi–Sugeno (T‐S) fuzzy theory, this paper focuses on the adaptive control of fractional‐order time‐delay systems involving unknown parameters and input saturations. T‐S fuzzy systems with “IF‐THEN” rules are employed to describe fractional‐order nonlinear systems. The influence of input saturation is handled by designing an auxiliary system. By using a norm conversion, the system's time‐delay term is converted into a non‐delayed form. Adaptive updating rules are devised to evaluate uncertain… Show more

“…As is well know, in the modeling process of a real system, there are usually some differences between the controlled object and its mathematical model, which can be reflected in the external disturbance, unmodeled dynamics and parameter variation [26,27]. For the synchronization of uncertain FOCSs, sliding-mode control (SMC) is a common and effective method, which originates from variable-structure control systems and is robust to uncertainty and disturbance [28].…”

Adaptive Terminal Sliding-Mode Synchronization Control with Chattering Elimination for a Fractional-Order Chaotic System

“…As is well know, in the modeling process of a real system, there are usually some differences between the controlled object and its mathematical model, which can be reflected in the external disturbance, unmodeled dynamics and parameter variation [26,27]. For the synchronization of uncertain FOCSs, sliding-mode control (SMC) is a common and effective method, which originates from variable-structure control systems and is robust to uncertainty and disturbance [28].…”

Adaptive Terminal Sliding-Mode Synchronization Control with Chattering Elimination for a Fractional-Order Chaotic System