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Bibliographic Details
Main Authors: Fasiku, Damilola, Tang, Wentao
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.27396
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author Fasiku, Damilola
Tang, Wentao
author_facet Fasiku, Damilola
Tang, Wentao
contents To reduce complexity and achieve scalable performance in high-dimensional black-box settings, we propose a distributed method for nonconvex derivative-free optimization of continuous variables with an additively separable objective, subject to linear equality constraints. The approach is built upon the alternating direction method of multipliers (ADMM) as the distributed optimization framework. To handle general, potentially complicating linear equality constraints beyond the standard ADMM formulation, we employ a two-level ADMM structure: an inner layer that performs sequential ADMM updates, and an outer layer that drives an introduced slack variable to zero via the method of multipliers. In addition, each subproblem is solved inexactly using a derivative-free trust-region solver, ensuring suboptimality within a decreasing, theoretically controlled error tolerance. This inexactness is critical for both computational efficiency and practical applicability in black-box settings, where exact solutions are impractical or overly expensive. We establish theoretical convergence of the proposed approach to an approximate solution, and demonstrate improved computational efficiency over monolithic derivative-free optimization approaches on challenging high-dimensional benchmarks, as well as effective performance on a distributed learning problem.
format Preprint
id arxiv_https___arxiv_org_abs_2510_27396
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Distributed Derivative-Free Optimization Using Inexact ADMM and Trust-Region Methods
Fasiku, Damilola
Tang, Wentao
Optimization and Control
To reduce complexity and achieve scalable performance in high-dimensional black-box settings, we propose a distributed method for nonconvex derivative-free optimization of continuous variables with an additively separable objective, subject to linear equality constraints. The approach is built upon the alternating direction method of multipliers (ADMM) as the distributed optimization framework. To handle general, potentially complicating linear equality constraints beyond the standard ADMM formulation, we employ a two-level ADMM structure: an inner layer that performs sequential ADMM updates, and an outer layer that drives an introduced slack variable to zero via the method of multipliers. In addition, each subproblem is solved inexactly using a derivative-free trust-region solver, ensuring suboptimality within a decreasing, theoretically controlled error tolerance. This inexactness is critical for both computational efficiency and practical applicability in black-box settings, where exact solutions are impractical or overly expensive. We establish theoretical convergence of the proposed approach to an approximate solution, and demonstrate improved computational efficiency over monolithic derivative-free optimization approaches on challenging high-dimensional benchmarks, as well as effective performance on a distributed learning problem.
title Distributed Derivative-Free Optimization Using Inexact ADMM and Trust-Region Methods
topic Optimization and Control
url https://arxiv.org/abs/2510.27396