English

Control Closure Certificates

Logic in Computer Science 2025-08-07 v1 Systems and Control Systems and Control

Abstract

This paper introduces the notion of control closure certificates to synthesize controllers for discrete-time control systems against ω\omega-regular specifications. Typical functional approaches to synthesize controllers against ω\omega-regular specifications rely on combining inductive invariants (for example, via barrier certificates) with proofs of well-foundedness (for example, via ranking functions). Transition invariants, provide an alternative where instead of standard well-foundedness arguments one may instead search for disjunctive well-foundedness arguments that together ensure a well-foundedness argument. Closure certificates, functional analogs of transition invariants, provide an effective, automated approach to verify discrete-time dynamical systems against linear temporal logic and ω\omega-regular specifications. We build on this notion to synthesize controllers to ensure the satisfaction of ω\omega-regular specifications. To do so, we first illustrate how one may construct control closure certificates to visit a region infinitely often (or only finitely often) via disjunctive well-founded arguments. We then combine these arguments to provide an argument for parity specifications. Thus, finding an appropriate control closure certificate over the product of the system and a parity automaton specifying a desired ω\omega-regular specification ensures that there exists a controller κ\kappa to enforce the ω\omega-regular specification. We propose a sum-of-squares optimization approach to synthesize such certificates and demonstrate their efficacy in designing controllers over some case studies.

Keywords

Cite

@article{arxiv.2508.03947,
  title  = {Control Closure Certificates},
  author = {Vishnu Murali and Mohammed Adib Oumer and Majid Zamani},
  journal= {arXiv preprint arXiv:2508.03947},
  year   = {2025}
}

Comments

28 pages, 4 figures, 6 Tables. To appear in International Symposium on Automated Technology for Verification and Analysis (ATVA), 2025

R2 v1 2026-07-01T04:36:15.437Z