A Spectral Perspective on Stochastic Control Barrier Functions
Abstract
Stochastic control barrier functions (SCBFs) provide a safety-critical control framework for systems subject to stochastic disturbances by bounding the probability of remaining within a safe set. However, synthesizing a valid SCBF that explicitly reflects the true safety probability of the system, which is the most natural measure of safety, remains a challenge. This paper addresses this issue by adopting a spectral perspective, utilizing the linear operator that governs the evolution of the closed-loop system's safety probability. We find that the dominant eigenpair of this Koopman-like operator encodes fundamental safety information of the stochastic system. The dominant eigenfunction is a natural and valid SCBF, with values that explicitly quantify the relative long-term safety of the state, while the dominant eigenvalue indicates the global rate at which the safety probability decays. A practical synthesis algorithm is proposed, termed power-policy iteration, which jointly computes the dominant eigenpair and an optimized backup policy. The method is validated using simulation experiments on safety-critical dynamics models.
Cite
@article{arxiv.2603.19813,
title = {A Spectral Perspective on Stochastic Control Barrier Functions},
author = {Inkyu Jang and Chams E. Mballo and Claire J. Tomlin and H. Jin Kim},
journal= {arXiv preprint arXiv:2603.19813},
year = {2026}
}
Comments
16 pages, 7 figures. This work has been submitted to the IEEE for possible publication