Adaptive discrete-time neural prescribed performance control: A safe control approach

• Published in: Neural networks Vol. 184; p. 107025
• Main Authors: Wu, Zhonghua, Huang, Bo, Bu, Xiangwei
• Format: Journal Article
• Language: English
• Published: United States Elsevier Ltd 01.04.2025
• Subjects: Adaptive backstepping control; Algorithms; Computer Simulation; Discrete-time; Feedback; Humans; Input saturation; Neural networks; Neural Networks, Computer; Nonlinear Dynamics; Prescribed performance control; Time Factors; Adaptive backstepping control; Input saturation; Discrete-time; Neural networks; Prescribed performance control
• ISSN: 0893-6080; 1879-2782; 1879-2782
• DOI: 10.1016/j.neunet.2024.107025

Most existing results on prescribed performance control (PPC), subject to input saturation and initial condition limitations, focus on continuous-time nonlinear systems. This article, as regards discrete-time nonlinear systems, is dedicated to constructing a novel adaptive switching control strategy to circumvent the singular problem when the PPC undergoes input saturation, while the initial conditions of the system can be released under the framework of PPC. The main design steps and characteristics include: (1) By devising a new discrete-time global finite-time performance function (DTGFTPF), the constructed performance boundary is shown to survive insensitive to arbitrary initial values, which present in the system; (2) A discrete-time adaptive finite-time prescribed performance controller (DTAFPPC) and a discrete-time adaptive backstepping controller (DTABC) are constructed, simultaneously. The DTAFPPC possesses the capability to drive tracking error convergence within preset boundaries within a finite time. In the presence of input saturation, the DTABC is applied to prevent system instability while permitting tracking error to occasionally exceed performance bounds without compromising overall stability; and (3) To overcome non-causal problems inherent in backstepping designs, the current moment values of the errors are integrated into the controllers and the adaptive update laws. The stability of the closed-loop system is validated through Lyapunov analysis theory and simulations. •A novel DTGFTPF is introduced in a discrete-time unknown strict-feedback system.•To mitigate the instability arising from input saturation in DTPPC, we propose a DTAFPPC and a DTABC.•The design of controllers and adaptive laws introduces a present moment error, effectively addressing this noncausal issue.