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Multivariate Monotone Inclusions in Saddle Form

Author

Listed:
  • Minh N. Bùi

    (Department of Mathematics, North Carolina State University, Raleigh, North Carolina 27695)

  • Patrick L. Combettes

    (Department of Mathematics, North Carolina State University, Raleigh, North Carolina 27695)

Abstract

We propose a novel approach to monotone operator splitting based on the notion of a saddle operator. Under investigation is a highly structured multivariate monotone inclusion problem involving a mix of set-valued, cocoercive, and Lipschitzian monotone operators, as well as various monotonicity-preserving operations among them. This model encompasses most formulations found in the literature. A limitation of existing primal-dual algorithms is that they operate in a product space that is too small to achieve full splitting of our problem in the sense that each operator is used individually. To circumvent this difficulty, we recast the problem as that of finding a zero of a saddle operator that acts on a bigger space. This leads to an algorithm of unprecedented flexibility, which achieves full splitting, exploits the specific attributes of each operator, is asynchronous, and requires to activate only blocks of operators at each iteration, as opposed to activating all of them. The latter feature is of critical importance in large-scale problems. The weak convergence of the main algorithm is established, as well as the strong convergence of a variant. Various applications are discussed, and instantiations of the proposed framework in the context of variational inequalities and minimization problems are presented.

Suggested Citation

  • Minh N. Bùi & Patrick L. Combettes, 2022. "Multivariate Monotone Inclusions in Saddle Form," Mathematics of Operations Research, INFORMS, vol. 47(2), pages 1082-1109, May.
  • Handle: RePEc:inm:ormoor:v:47:y:2022:i:2:p:1082-1109
    DOI: 10.1287/moor.2021.1161
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    References listed on IDEAS

    as
    1. Heinz H. Bauschke & Patrick L. Combettes, 2001. "A Weak-to-Strong Convergence Principle for Fejér-Monotone Methods in Hilbert Spaces," Mathematics of Operations Research, INFORMS, vol. 26(2), pages 248-264, May.
    2. Xiangfeng Wang & Junping Zhang & Wenxing Zhang, 2020. "The distance between convex sets with Minkowski sum structure: application to collision detection," Computational Optimization and Applications, Springer, vol. 77(2), pages 465-490, November.
    3. Xiaohan Yan & Jacob Bien, 2021. "Rare Feature Selection in High Dimensions," Journal of the American Statistical Association, Taylor & Francis Journals, vol. 116(534), pages 887-900, April.
    4. Patrick R. Johnstone & Jonathan Eckstein, 2021. "Single-forward-step projective splitting: exploiting cocoercivity," Computational Optimization and Applications, Springer, vol. 78(1), pages 125-166, January.
    5. Jonathan Eckstein, 2017. "A Simplified Form of Block-Iterative Operator Splitting and an Asynchronous Algorithm Resembling the Multi-Block Alternating Direction Method of Multipliers," Journal of Optimization Theory and Applications, Springer, vol. 173(1), pages 155-182, April.
    6. Luis M. Briceño-Arias & Giovanni Chierchia & Emilie Chouzenoux & Jean-Christophe Pesquet, 2019. "A random block-coordinate Douglas–Rachford splitting method with low computational complexity for binary logistic regression," Computational Optimization and Applications, Springer, vol. 72(3), pages 707-726, April.
    7. Min Li & Xiaoming Yuan, 2015. "A Strictly Contractive Peaceman-Rachford Splitting Method with Logarithmic-Quadratic Proximal Regularization for Convex Programming," Mathematics of Operations Research, INFORMS, vol. 40(4), pages 842-858, October.
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