Razumikhin and Krasovskii Approaches for Safe Stabilization

TL;DR

This paper introduces novel control Lyapunov and barrier functions for nonlinear time-delay systems, enabling safe stabilization through Razumikhin and Krasovskii approaches, and proposes a sliding mode control method for practical implementation.

Contribution

It extends delay-free control functions to time-delay systems and develops a sliding mode control approach for combined stabilization and safety.

Findings

Successfully applied to automotive cruise control systems.

Effective in multi-agent system synchronization.

Provides closed-form controllers for delay systems.

Abstract

This paper studies the stabilization and safety problems of nonlinear time-delay systems. Following both Razumikhin and Krasovskii approaches, we propose novel control Lyapunov functions/functionals for the stabilization problem and novel control barrier functions/functionals for the safety problem. The proposed control Lyapunov and barrier functions/functionals extend the existing ones from the delay-free case to the time-delay case, and allow for designing the stabilizing and safety controllers in closed-form. Since analytical solutions to time-delay optimal control problems are hard to be achieved, a sliding mode control based approach is developed to merge the proposed control Lyapunov and barrier functions/functionals. Based on the sliding surface functional, a feedback control law is established to investigate the stabilization and safety objectives simultaneously. In particular, the properties of the sliding surface functional are analyzed, and further how to construct the sliding surface functional is discussed. Finally, the proposed approaches are illustrated via two numerical examples from the connected cruise control problem of automotive systems and the synchronization problem of multi-agent systems.