Stochastic proximal gradient methods for nonconvex problems in Hilbert spaces

For finite-dimensional problems, stochastic approximation methods have long been used to solve stochastic optimization problems. Their application to infinite-dimensional problems is less understood, particularly for nonconvex objectives. This paper presents convergence results for the stochastic pr...

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Vydané v:Computational optimization and applications Ročník 78; číslo 3; s. 705 - 740
Hlavní autori: Geiersbach, Caroline, Scarinci, Teresa
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: New York, NY Springer US 01.04.2021
Springer Nature B.V
Predmet:
Algorithms
Approximation
Constraints
Continuity (mathematics)
Convergence
Convex and Discrete Geometry
Differential inclusions
Hilbert space
Management Science
Mathematical programming methods
Mathematics
Mathematics and Statistics
Nonsmooth and nonconvex optimization
Operations Research
Operations Research/Decision Theory
Optimal control problems involving partial differential equations
Optimization
Partial differential equations
Partial differential equations with randomness
Statistics
Stochastic programming
Differential inclusions
Optimal control problems involving partial differential equations
Partial differential equations with randomness
Nonsmooth and nonconvex optimization
Mathematical programming methods
Stochastic programming
ISSN:1573-2894, 0926-6003, 1573-2894
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Shrnutí:For finite-dimensional problems, stochastic approximation methods have long been used to solve stochastic optimization problems. Their application to infinite-dimensional problems is less understood, particularly for nonconvex objectives. This paper presents convergence results for the stochastic proximal gradient method applied to Hilbert spaces, motivated by optimization problems with partial differential equation (PDE) constraints with random inputs and coefficients. We study stochastic algorithms for nonconvex and nonsmooth problems, where the nonsmooth part is convex and the nonconvex part is the expectation, which is assumed to have a Lipschitz continuous gradient. The optimization variable is an element of a Hilbert space. We show almost sure convergence of strong limit points of the random sequence generated by the algorithm to stationary points. We demonstrate the stochastic proximal gradient algorithm on a tracking-type functional with a L1\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$L^1$$\end{document}-penalty term constrained by a semilinear PDE and box constraints, where input terms and coefficients are subject to uncertainty. We verify conditions for ensuring convergence of the algorithm and show a simulation.
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ISSN:1573-2894
0926-6003
1573-2894
DOI:10.1007/s10589-020-00259-y