Perturbed Gradient Descent Algorithms are Small-Disturbance Input-to-State Stable
Abstract
This article investigates the robustness of gradient descent algorithms under perturbations. The concept of small-disturbance input-to-state stability (ISS) for discrete-time nonlinear dynamical systems is introduced, along with its Lyapunov characterization. The conventional linear Polyak-Lojasiewicz (PL) condition is then extended to a nonlinear version, and it is shown that the gradient descent algorithm is small-disturbance ISS provided the objective function satisfies the generalized nonlinear PL condition. This small-disturbance ISS property guarantees that the gradient descent algorithm converges to a small neighborhood of the optimum under sufficiently small perturbations. As a direct application of the developed framework, we demonstrate that the LQR cost satisfies the generalized nonlinear PL condition, thereby establishing that the policy gradient algorithm for LQR is small-disturbance ISS. Additionally, other popular policy gradient algorithms, including natural policy gradient and Gauss-Newton method, are also proven to be small-disturbance ISS.
Cite
@article{arxiv.2507.02131,
title = {Perturbed Gradient Descent Algorithms are Small-Disturbance Input-to-State Stable},
author = {Leilei Cui and Zhong-Ping Jiang and Eduardo D. Sontag and Richard D. Braatz},
journal= {arXiv preprint arXiv:2507.02131},
year = {2025}
}
Comments
16 pages