2023
DOI: 10.1007/s10107-022-01922-4
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Constrained composite optimization and augmented Lagrangian methods

Abstract: We investigate finite-dimensional constrained structured optimization problems, featuring composite objective functions and set-membership constraints. Offering an expressive yet simple language, this problem class provides a modeling framework for a variety of applications. We study stationarity and regularity concepts, and propose a flexible augmented Lagrangian scheme. We provide a theoretical characterization of the algorithm and its asymptotic properties, deriving convergence results for fully nonconvex p… Show more

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Cited by 16 publications
(29 citation statements)
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“…holds. Now, setting µ = µ * , λ = λ * , ν x i = αs ρ i − α x i (i ∈ I 0 (x * )) and ν y i = αx * i − α y i (i ∈ I 0 (y * )) for an arbitrary α > 0, we see that ( 13) is a direct consequence of (12). Moreover, for…”
Section: An Exact Penalty Algorithmmentioning
confidence: 88%
See 1 more Smart Citation
“…holds. Now, setting µ = µ * , λ = λ * , ν x i = αs ρ i − α x i (i ∈ I 0 (x * )) and ν y i = αx * i − α y i (i ∈ I 0 (y * )) for an arbitrary α > 0, we see that ( 13) is a direct consequence of (12). Moreover, for…”
Section: An Exact Penalty Algorithmmentioning
confidence: 88%
“…The class of nonconvex approximation schemes usually replaces the ℓ 0 -term in (SPO) by a nonconvex penalty function. One possibility is to use the ℓ p -quasi-norm for p ∈ (0, 1), see, e.g., [11,12], which has nicer properties than the ℓ 0 -norm, e.g., it is continuous. However, despite its nonconvexity, it also fails to be Lipschitz continuous.…”
Section: Introductionmentioning
confidence: 99%
“…Nonsmooth composite problems like (P) have been extensively studied in the past decades, but most often with convex (or even polyhedral) nonsmooth term g; see [22,35,48]. Prominent special cases of (P) are nonlinear [4] and disjunctive [2] programming, structured optimization [39,47], and constrained structured optimization [17]. The abstract problem (P) is also referred to as "extended nonlinear programming" in [43], promoting better representation of structures found in applications by featuring a composite term, beyond the conventional format of nonlinear programming.…”
Section: Introductionmentioning
confidence: 99%
“…subject to c(x) − z = 0, (P S ) which has a simpler, separable objective function but is subject to some (explicit) constraints. It has been observed in [17,Lemma 3.1] that incorporating auxiliary variables in this manner does not affect minimizers and stationary points when compared to the original (P) -somewhat remarkably in light of [3]. A fundamental technique for solving constrained optimization problems such as (P S ) is the augmented Lagrangian (AL) framework [4,6,42], which can also effortlessly handle nonsmoothness [17,18,21,23].…”
Section: Introductionmentioning
confidence: 99%
“…for some penalty parameter ρ k > 0. Since the squared distance function y → dist 2 (y, C) is continuously differentiable by convexity of C, see [7,Corollary 12.30], this subproblem has exactly the structure of the composite optimization problem (P) and can therefore, in principle, be solved by a proximal gradient method, see [21,24,27,28] for suitable realizations of this approach.…”
mentioning
confidence: 99%