English

Separable Approximations and Decomposition Methods for the Augmented Lagrangian

Optimization and Control 2013-09-02 v1 Distributed, Parallel, and Cluster Computing Numerical Analysis Machine Learning

Abstract

In this paper we study decomposition methods based on separable approximations for minimizing the augmented Lagrangian. In particular, we study and compare the Diagonal Quadratic Approximation Method (DQAM) of Mulvey and Ruszczy\'{n}ski and the Parallel Coordinate Descent Method (PCDM) of Richt\'arik and Tak\'a\v{c}. We show that the two methods are equivalent for feasibility problems up to the selection of a single step-size parameter. Furthermore, we prove an improved complexity bound for PCDM under strong convexity, and show that this bound is at least 8(L/Lˉ)(ω1)28(L'/\bar{L})(\omega-1)^2 times better than the best known bound for DQAM, where ω\omega is the degree of partial separability and LL' and Lˉ\bar{L} are the maximum and average of the block Lipschitz constants of the gradient of the quadratic penalty appearing in the augmented Lagrangian.

Keywords

Cite

@article{arxiv.1308.6774,
  title  = {Separable Approximations and Decomposition Methods for the Augmented Lagrangian},
  author = {Rachael Tappenden and Peter Richtarik and Burak Buke},
  journal= {arXiv preprint arXiv:1308.6774},
  year   = {2013}
}

Comments

28 pages, 6 algorithms, 2 figures

R2 v1 2026-06-22T01:18:02.103Z