Complexity of an inexact stochastic SQP algorithm for equality constrained optimization
Abstract
In this paper, we consider nonlinear optimization problems with a stochastic objective function and deterministic equality constraints. We propose an inexact two-stepsize stochastic sequential quadratic programming (SQP) algorithm and analyze its worst-case complexity under mild assumptions. The method utilizes a step decomposition strategy and handles stochastic gradient estimates by assigning different stepsizes to different components of the search direction. We establish the first known worst-case complexity with respect to the infeasibility measure when no constraint qualification is assumed and a worst-case complexity of when LICQ holds, matching the best known result in the literature. In addition, under mild conditions, our method achieves the optimal complexity with respect to the gradient of the Lagrangian regardless of constraint qualifications. Our results provide the first complexity guarantees for the popular Byrd-Omojukun step decomposition strategy and verify its theoretical efficacy. Numerical experiments show that our algorithm has a superior infeasibility convergence performance and a competitive KKT convergence rate compared to the state-of-the-art stochastic SQP method.
Cite
@article{arxiv.2604.14351,
title = {Complexity of an inexact stochastic SQP algorithm for equality constrained optimization},
author = {Michael J. O'Neill and Aoji Tang},
journal= {arXiv preprint arXiv:2604.14351},
year = {2026}
}