English

Large-scale nonconvex optimization: randomization, gap estimation, and numerical resolution

Optimization and Control 2023-06-19 v3

Abstract

We address a large-scale and nonconvex optimization problem, involving an aggregative term. This term can be interpreted as the sum of the contributions of N agents to some common good, with N large. We investigate a relaxation of this problem, obtained by randomization. The relaxation gap is proved to converge to zeros as N goes to infinity, independently of the dimension of the aggregate. We propose a stochastic method to construct an approximate minimizer of the original problem, given an approximate solution of the randomized problem. McDiarmid's concentration inequality is used to quantify the probability of success of the method. We consider the Frank-Wolfe (FW) algorithm for the resolution of the randomized problem. Each iteration of the algorithm requires to solve a subproblem which can be decomposed into N independent optimization problems. A sublinear convergence rate is obtained for the FW algorithm. In order to handle the memory overflow problem possibly caused by the FW algorithm, we propose a stochastic Frank-Wolfe (SFW) algorithm, which ensures the convergence in both expectation and probability senses. Numerical experiments on a mixed-integer quadratic program illustrate the efficiency of the method.

Keywords

Cite

@article{arxiv.2204.02366,
  title  = {Large-scale nonconvex optimization: randomization, gap estimation, and numerical resolution},
  author = {J. Frédéric Bonnans and Kang Liu and Nadia Oudjane and Laurent Pfeiffer and Cheng Wan},
  journal= {arXiv preprint arXiv:2204.02366},
  year   = {2023}
}

Comments

33 pages, 3 figures

R2 v1 2026-06-24T10:38:51.792Z