English

Zeroth-Order Constrained Optimization from a Control Perspective via Feedback Linearization

Optimization and Control 2026-01-29 v2 Systems and Control Systems and Control

Abstract

Safe derivative-free optimization under unknown constraints is a fundamental challenge in modern learning and control. Existing zeroth-order (ZO) methods typically still assume access to a first-order oracle of the constraint functions or restrict attention to convex settings, leaving nonconvex optimization with black-box constraints largely unexplored. We propose the zeroth-order feedback-linearization (ZOFL) algorithm for ZO constrained optimization that enforces feasibility without access to the first-order oracle of the constraint functions and applies to both equality and inequality constraints. The proposed approach relies only on noisy, sample-based gradient estimates obtained via two-point estimators, yet provably guarantees constraint satisfaction under mild regularity conditions. It adopts a control-theoretic perspective on ZO constrained optimization and leverages feedback linearization, a nonlinear control technique, to enforce feasibility. Finite-time bounds on constraint violation and asymptotic global convergence guarantees are established for the ZOFL algorithm. A midpoint discretization variant is further developed to improve feasibility without sacrificing optimality. Empirical results demonstrate that ZOFL consistently outperforms standard ZO baselines, achieving competitive objective values while maintaining feasibility.

Keywords

Cite

@article{arxiv.2509.24056,
  title  = {Zeroth-Order Constrained Optimization from a Control Perspective via Feedback Linearization},
  author = {Runyu Zhang and Gioele Zardini and Asuman Ozdaglar and Jeff Shamma and Na Li},
  journal= {arXiv preprint arXiv:2509.24056},
  year   = {2026}
}
R2 v1 2026-07-01T06:03:00.578Z