Safety-Critical Control With Input Delay in Dynamic Environment

Endowing nonlinear systems with safe behavior is increasingly important in modern control. This task is particularly challenging for real-life control systems that operate in dynamically changing environments. This article develops a framework for safety-critical control in dynamic environments, by establishing the notion of environmental control barrier functions (ECBFs). Importantly, the framework is able to guarantee safety even in the presence of input delay, by accounting for the evolution of the environment during the delayed response of the system. The underlying control synthesis relies on predicting the future state of the system and the environment over the delay interval, with robust safety guarantees against prediction errors. The efficacy of the proposed method is demonstrated by a simple adaptive cruise control (ACC) problem and a more complex robotics application on a Segway platform.

Automated summary

This article develops a framework for safety-critical control in dynamic environments by introducing the concept of environmental control barrier functions (ECBFs). This framework can guarantee safety even with input delay by considering the evolution of the environment during the delayed response of the system. The proposed method is demonstrated to be effective in a simple adaptive cruise control (ACC) problem and a more complex robotics application on a Segway platform.