Recurrent Control Barrier Functions: A Path Towards Nonparametric Safety Verification
Abstract
Ensuring the safety of complex dynamical systems often relies on Hamilton-Jacobi (HJ) Reachability Analysis or Control Barrier Functions (CBFs). Both methods require computing a function that characterizes a safe set that can be made (control) invariant. However, the computational burden of solving high-dimensional partial differential equations (for HJ Reachability) or large-scale semidefinite programs (for CBFs) makes finding such functions challenging. In this paper, we introduce the notion of Recurrent Control Barrier Functions (RCBFs), a novel class of CBFs that leverages a recurrent property of the trajectories, i.e., coming back to a safe set, for safety verification. Under mild assumptions, we show that the RCBF condition holds for the signed-distance function, turning function design into set identification. Notably, the resulting set need not be invariant to certify safety. We further propose a data-driven nonparametric method to compute safe sets that is massively parallelizable and trades off conservativeness against computational cost.
Cite
@article{arxiv.2510.02127,
title = {Recurrent Control Barrier Functions: A Path Towards Nonparametric Safety Verification},
author = {Jixian Liu and Enrique Mallada},
journal= {arXiv preprint arXiv:2510.02127},
year = {2025}
}
Comments
8 Pages, 3 Figures