Fixed-time safe tracking control of uncertain high-order nonlinear pure-feedback systems via unified transformation functions
Chaoqun Guo, Jiangping Hu, Jiasheng Hao, Sergej Čelikovský, Xiaoming Hu
Abstract
In this paper, a fixed-time safe control problem is investigated for an uncertain high-order nonlinear pure-feedback system with state constraints.A new nonlinear transformation function is firstly proposed to handle both the constrained and unconstrained cases in a unified way.Further, a radial basis function neural network is constructed to approximate the unknown dynamics in the system and a fixed-time dynamic surface control (FDSC) technique is developed to facilitate the fixed-time control design for the uncertain high-order pure-feedback system.Combined with the proposed unified transformation function and the FDSC technique, an adaptive fixed-time control strategy is proposed to guarantee the fixed-time tracking.The novel original results of the paper allow to design the independent unified flexible fixed-time control strategy taking into account the actual possible constraints, either present or missing.Numerical examples are presented to demonstrate the proposed fixed-time tracking control strategy.