English

Discrete implementations of sliding-mode controllers with barrier-function adaptations require a revised framework

Systems and Control 2025-02-24 v1 Systems and Control

Abstract

Challenges in the discrete implementation of sliding-mode controllers (SMC) with barrier-function-based adaptations are analyzed, revealing fundamental limitations in conventional design frameworks. It is shown that under uniform sampling, the original continuous-time problem motivating these controllers becomes theoretically unsolvable under standard assumptions. To address this incompatibility, a revised control framework is proposed, explicitly incorporating actuator capacity constraints and sampled-data dynamics. Within this structure, the behavior of barrier function-based adaptive controllers (BFASMC) is rigorously examined, explaining their empirical success in digital implementations. A key theoretical result establishes an explicit relation between the actuator capacity, the sampling rate, and the width of the barrier function, providing a principled means to tune these controllers for different application requirements. This relation enables the resolution of various design problems with direct practical implications. A modified BFASMC is then introduced, systematically leveraging sampling effects to ensure finite-time convergence to a positively invariant predefined set, a key advancement for guaranteeing predictable safety margins.

Keywords

Cite

@article{arxiv.2502.15201,
  title  = {Discrete implementations of sliding-mode controllers with barrier-function adaptations require a revised framework},
  author = {Luis Ovalle and Andrés González and Leonid Fridman and Hernan Haimovich},
  journal= {arXiv preprint arXiv:2502.15201},
  year   = {2025}
}
R2 v1 2026-06-28T21:52:21.995Z