A Parallel Splitting Method for Coupled Monotone Inclusions

To cite this version:Hedy Attouch, Jérôme Bolte, Benar Svaiter. Convergence of descent methods for semi-algebraic and tame problems: proximal algorithms, forward-backward splitting, and regularized Gauss-Seidel methods. Math. Program., Ser. A, 2011, 137 (1), pp.91-124. <10.1007/s10107-011-0484-9>. Convergence of descent methods for semi-algebraic and tame problems: proximal algorithms, forward-backward splitting, and regularized Gauss-Seidel methods , 15, 2010; revised: July, 21, 2011 Abstract In view of the minimization of a nonsmooth nonconvex function f , we prove an abstract convergence result for descent methods satisfying a sufficient-decrease assumption, and allowing a relative error tolerance. Our result guarantees the convergence of bounded sequences, under the assumption that the function f satisfies the Kurdyka-Lojasiewicz inequality. This assumption allows to cover a wide range of problems, including nonsmooth semi-algebraic (or more generally tame) minimization. The specialization of our result to different kinds of structured problems provides several new convergence results for inexact versions of the gradient method, the proximal method, the forward-backward splitting algorithm, the gradient projection and some proximal regularization of the Gauss-Seidel method in a nonconvex setting. Our results are illustrated through feasibility problems, or iterative thresholding procedures for compressive sensing.2010 Mathematics Subject Classification: 34G25, 47J25, 47J30, 47J35, 49M15, 49M37, 65K15, 90C25, 90C53.

show abstract

“…The Lipschitz constant of ∇h is denoted by L. This kind of structured problem occurs frequently, see for instance [25,6] and Example 5.4.…”

Section: Inexact Forward-backward Algorithmmentioning

confidence: 99%

Convergence of descent methods for semi-algebraic and tame problems: proximal algorithms, forward–backward splitting, and regularized Gauss–Seidel methods

2011

View full text Add to dashboard Cite

show abstract

“…The wealth and applicability of this notion is illustrated through the following examples (one can consult [5] for further examples): Proposition 3.13. Let T : H ⇉ H be a maximal monotone operator.…”

Section: The Case λ Constantmentioning

confidence: 99%

A Continuous Dynamical Newton-Like Approach to Solving Monotone Inclusions

Attouch¹,

Svaiter²

2011

SIAM J. Control Optim.

132

View full text Add to dashboard Cite

We introduce non-autonomous continuous dynamical systems which are linked to the Newton and Levenberg-Marquardt methods. They aim at solving inclusions governed by maximal monotone operators in Hilbert spaces. Relying on the Minty representation of maximal monotone operators as lipschitzian manifolds, we show that these dynamics can be formulated as first-order in time differential systems, which are relevant to the Cauchy-Lipschitz theorem. By using Lyapunov methods, we prove that their trajectories converge weakly to equilibria. Time discretization of these dynamics gives algorithms providing new insight into Newton's method for solving monotone inclusions.2010 Mathematics Subject Classification: 34G25, 47J25, 47J30, 47J35, 49M15, 49M37, 65K15, 90C25, 90C53.

show abstract

“…Domains of application. The method developed in this paper can be applied to find Wardrop equilibria for network flows and construct best approximations for the convex feasibility problem (see [5]), as well as domain decomposition methods for PDE's [4] and optimal control problems [7] or best response dynamics for potential games [4]. Here we discuss on the problem of finding the sparsest solutions of underdetermined systems of equations.…”

Section: Application Issuesmentioning

confidence: 99%

“…However, they tend to be less stable than the implicit ones. An abundant literature has been devoted to the study of the forward-backward algorithms, and their many applications, see [5,Attouch,Briceño and Combettes], [18,Combettes and Wajs] and the references therein. Thus the main original aspect of our approach is to show how such algorithms can be combined with penalization methods.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Coupling Forward-Backward with Penalty Schemes and Parallel Splitting for Constrained Variational Inequalities

Attouch¹,

Czarnecki²,

Peypouquet³

2011

SIAM J. Optim.

Self Cite

View full text Add to dashboard Cite

Abstract. We are concerned with the study of a class of forward-backward penalty schemes for solving variational inequalities 0 ∈ Ax + NC (x) where H is a real Hilbert space, A : H ⇉ H is a maximal monotone operator, and NC is the outward normal cone to a closed convex set C ⊂ H. Let Ψ : H → R be a convex differentiable function whose gradient is Lipschitz continuous, and which acts as a penalization function with respect to the constraint x ∈ C. Given a sequence (βn) of penalization parameters which tends to infinity, and a sequence of positive time steps (λn) ∈ ℓ 2 \ ℓ 1 , we consider the diagonal forward-backward algorithm xn+1 = (I + λnA) −1 (xn − λnβn∇Ψ(xn)).Assuming that (βn) satisfies the growth condition lim sup n→∞ λnβn < 2/θ (where θ is the Lipschitz constant of ∇Ψ), we obtain weak ergodic convergence of the sequence (xn) to an equilibrium for a general maximal monotone operator A. We also obtain weak convergence of the whole sequence (xn) when A is the subdifferential of a proper lower-semicontinuous convex function. As a key ingredient of our analysis, we use the cocoerciveness of the operator ∇Ψ. When specializing our results to coupled systems, we bring new light on Passty's Theorem, and obtain convergence results of new parallel splitting algorithms for variational inequalities involving coupling in the constraint. We also establish robustness and stability results that account for numerical approximation errors. An illustration to compressive sensing is given.

show abstract

A Parallel Splitting Method for Coupled Monotone Inclusions

Cited by 94 publications

References 54 publications

Convergence of descent methods for semi-algebraic and tame problems: proximal algorithms, forward–backward splitting, and regularized Gauss–Seidel methods

Convergence of descent methods for semi-algebraic and tame problems: proximal algorithms, forward–backward splitting, and regularized Gauss–Seidel methods

A Continuous Dynamical Newton-Like Approach to Solving Monotone Inclusions

Coupling Forward-Backward with Penalty Schemes and Parallel Splitting for Constrained Variational Inequalities

Contact Info

Product

Resources

About