English

Anytime-Feasible First-Order Optimization via Safe Sequential QCQP

Optimization and Control 2025-11-26 v1 Robotics Systems and Control Systems and Control

Abstract

This paper presents the Safe Sequential Quadratically Constrained Quadratic Programming (SS-QCQP) algorithm, a first-order method for smooth inequality-constrained nonconvex optimization that guarantees feasibility at every iteration. The method is derived from a continuous-time dynamical system whose vector field is obtained by solving a convex QCQP that enforces monotonic descent of the objective and forward invariance of the feasible set. The resulting continuous-time dynamics achieve an O(1/t)O(1/t) convergence rate to first-order stationary points under standard constraint qualification conditions. We then propose a safeguarded Euler discretization with adaptive step-size selection that preserves this convergence rate while maintaining both descent and feasibility in discrete time. To enhance scalability, we develop an active-set variant (SS-QCQP-AS) that selectively enforces constraints near the boundary, substantially reducing computational cost without compromising theoretical guarantees. Numerical experiments on a multi-agent nonlinear optimal control problem demonstrate that SS-QCQP and SS-QCQP-AS maintain feasibility, exhibit the predicted convergence behavior, and deliver solution quality comparable to second-order solvers such as SQP and IPOPT.

Keywords

Cite

@article{arxiv.2511.19675,
  title  = {Anytime-Feasible First-Order Optimization via Safe Sequential QCQP},
  author = {Jiarui Wang and Mahyar Fazlyab},
  journal= {arXiv preprint arXiv:2511.19675},
  year   = {2025}
}
R2 v1 2026-07-01T07:53:07.770Z