Litcius/Paper detail

Generalization of Direct Adaptive Control Using Fractional Calculus Applied to Nonlinear Systems

Mohamed Aburakhis, Raúl Ordóñez

2024Journal of Control Automation and Electrical Systems12 citationsDOIOpen Access PDF

Abstract

Abstract This paper presents a new direct adaptive control (DAC) technique using Caputo’s definition of the fractional-order derivative. This is the first time a fractional-order adaptive law is introduced to work together with an integer-order stable manifold for approximating the uncertainty of a class of nonlinear systems. The DAC approach uses universal function approximators such as multi-layer perceptrons with one hidden layer or fuzzy systems to approximate the controller. This paper presents a new lemma, which elucidates and clarifies the link between the Caputo and the Riemann–Liouville definitions. The introduced lemma is useful in developing a Lyapunov candidate to prove the stability of using the proposed fractional-order adaptive law. This is further explained by a numerical example, which is provided to elucidate the practicality of using the fractional-order derivative for updating the approximator parameters. The main novelty of the results in this paper is a rigorous stability proof of the fractional DAC approach for a class of nonlinear systems that is subjected to unstructured uncertainty and deals with the adaptation mechanism using a traditional integer-order stable manifold. This makes the control scheme easier to implement in practice. The fractional-order adaptation law provides greater degrees of freedom and a potentially larger functional control structure than the conventional adaptive control. Finally, the paper demonstrates that traditional integer-order DAC is a special case of the more general fractional-order DAC scheme introduced here.

Topics & Concepts

Fractional calculusMathematicsNonlinear systemLemma (botany)Control theory (sociology)Adaptive controlStability (learning theory)Lyapunov functionMathematical optimizationComputer scienceApplied mathematicsControl (management)Artificial intelligencePoaceaePhysicsEcologyBiologyMachine learningQuantum mechanicsAdvanced Control Systems DesignAdaptive Control of Nonlinear SystemsAdvanced Control Systems Optimization