English

The inexact power augmented Lagrangian method for constrained nonconvex optimization

Optimization and Control 2025-11-25 v2 Machine Learning

Abstract

This work introduces an unconventional inexact augmented Lagrangian method where the augmenting term is a Euclidean norm raised to a power between one and two. The proposed algorithm is applicable to a broad class of constrained nonconvex minimization problems that involve nonlinear equality constraints. In a first part of this work, we conduct a full complexity analysis of the method under a mild regularity condition, leveraging an accelerated first-order algorithm for solving the H\"older-smooth subproblems. Interestingly, this worst-case result indicates that using lower powers for the augmenting term leads to faster constraint satisfaction, albeit with a slower decrease of the dual residual. Notably, our analysis does not assume boundedness of the iterates. Thereafter, we present an inexact proximal point method for solving the weakly-convex and H\"older-smooth subproblems, and demonstrate that the combined scheme attains an improved rate that reduces to the best-known convergence rate whenever the augmenting term is a classical squared Euclidean norm. Different augmenting terms, involving a lower power, further improve the primal complexity at the cost of the dual complexity. Finally, numerical experiments validate the practical performance of unconventional augmenting terms.

Keywords

Cite

@article{arxiv.2410.20153,
  title  = {The inexact power augmented Lagrangian method for constrained nonconvex optimization},
  author = {Alexander Bodard and Konstantinos Oikonomidis and Emanuel Laude and Panagiotis Patrinos},
  journal= {arXiv preprint arXiv:2410.20153},
  year   = {2025}
}

Comments

Accepted for publication in Transactions on Machine Learning Research

R2 v1 2026-06-28T19:36:37.091Z