Federica Porta scite author profile

We develop a new proximal-gradient method for minimizing the sum of a differentiable, possibly nonconvex, function plus a convex, possibly non differentiable, function. The key features of the proposed method are the definition of a suitable descent direction, based on the proximal operator associated to the convex part of the objective function, and an Armijo-like rule to determine the step size along this direction ensuring the sufficient decrease of the objective function. In this frame, we especially address the possibility of adopting a metric which may change at each iteration and an inexact computation of the proximal point defining the descent direction. For the more general nonconvex case, we prove that all limit points of the iterates sequence are stationary, while for convex objective functions we prove the convergence of the whole sequence to a minimizer, under the assumption that a minimizer exists. In the latter case, assuming also that the gradient of the smooth part of the objective function is Lipschitz, we also give a convergence rate estimate, showing the O( 1 k ) complexity with respect to the function values. We also discuss verifiable sufficient conditions for the inexact proximal point and we present the results of a numerical experience on a convex total variation based image restoration problem, showing that the proposed approach is competitive with another state-of-the-art method.

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On the convergence of a linesearch based proximal-gradient method for nonconvex optimization

Bonettini

Loris

Porta

et al. 2017

Inverse Problems

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We consider a variable metric linesearch based proximal gradient method for the minimization of the sum of a smooth, possibly nonconvex function plus a convex, possibly nonsmooth term. We prove convergence of this iterative algorithm to a critical point if the objective function satisfies the Kurdyka-Lojasiewicz property at each point of its domain, under the assumption that a limit point exists. The proposed method is applied to a wide collection of image processing problems and our numerical tests show that our algorithm results to be flexible, robust and competitive when compared to recently proposed approaches able to address the optimization problems arising in the considered applications.

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A Variable Metric Forward-Backward Method with Extrapolation

Bonettini¹,

Porta²,

Ruggiero³

2016

SIAM J. Sci. Comput.

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Forward-backward methods are a very useful tool for the minimization of a functional given by the sum of a differentiable term and a nondifferentiable one, and their investigation hascomprised several efforts from many researchers in the last decade. In this paper we focus on the convex case and, inspired by recent approaches for accelerating first-order iterative schemes, we\ud develop a scaled inertial forward-backward algorithm which is based on a metric changing at each iteration and on a suitable extrapolation step. Unlike standard forward-backward methods with extrapolation, our scheme is able to handle functions whose domain is not the entire space. Both an O(1/k^2) convergence rate estimate on the objective function values and the convergence of the sequence of the iterates are proved. Numerical experiments on several test problems arising from\ud image processing, compressed sensing, and statistical inference show the effectiveness of the proposed method in comparison to well-performing state-of-the-art algorithms

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A New Steplength Selection for Scaled Gradient Methods with Application to Image Deblurring

2015

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Gradient methods are frequently used in large scale image deblurring problems since they avoid the onerous computation of the Hessian matrix of the objective function. Second order information is typically sought by a clever choice of the steplength parameter defining the descent direction, as in the case of the wellknown Barzilai and Borwein rules. In a recent paper, a strategy for the steplength selection approximating the inverse of some eigenvalues of the Hessian matrix has been proposed for gradient methods applied to unconstrained minimization problems. In the quadratic case, this approach is based on a Lanczos process applied every m iterations to the matrix of the gradients computed in the previous m iterations, but the idea can be extended to a general objective function. In this paper we extend this rule to the case of scaled gradient projection methods applied to constrained minimization problems, and we test the effectiveness of the proposed strategy in image deblurring problems in both the presence and the absence of an explicit edge-preserving regularization term.

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Recent Advances in Variable Metric First-Order Methods

Bonettini

Porta

Prato

et al. 2019

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Federica Porta

Variable Metric Inexact Line-Search-Based Methods for Nonsmooth Optimization

On the convergence of a linesearch based proximal-gradient method for nonconvex optimization

A Variable Metric Forward-Backward Method with Extrapolation

A New Steplength Selection for Scaled Gradient Methods with Application to Image Deblurring

Recent Advances in Variable Metric First-Order Methods

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