Complexity of Adagrad and other first-order methods for nonconvex optimization problems with bounds  constraints

Philippe Toint

Complexity of Adagrad and other first-order methods for nonconvex optimization problems with bounds constraints

Philippe Toint

Namur Institute for Complex Systems

Research output: Working paper

7 Downloads (Pure)

Abstract

A parametric class of trust-region algorithms for constrained nonconvex optimization is analyzed, where the objective function is never computed. By defining appropriate first-order stationarity criteria, we are able to extend the Adagrad method to the newly considered problem and retrieve the standard complexity rate of the projected gradient method that uses both the gradient and objective function values. Furthermore, we propose an additional iteration-dependent scaling with slightly inferior theoretical guarantees. In both cases, the bounds are essentially sharp, and curvature information can be used to compute the stepsize. Initial experimental results for noisy bound-constrained instances illustrate the benefits of the objective-free approach.

Original language	English
Publisher	Arxiv
Volume	2406.15793
Publication status	Published - 10 Jul 2024

Access to Document

gjt7R1Submitted manuscript, 387 KBLicence: Unspecified

2 Working paper
1 Article
1 Discussion paper

A Stochastic Objective-Function-Free Adaptive Regularization Method with Optimal Complexity
Gratton, S., Jerad, S. & Toint, P., 10 Jul 2024, (Submitted) Arxiv, 32 p.
Research output: Working paper

File
Divergence of the ADAM algorithm with fixed-stepsize: a (very) simple example
TOINT, P., Aug 2023, Arxiv, 3 p.
Research output: Working paper › Discussion paper

File
OFFO minimization algorithms for second-order optimality and their complexity
Gratton, S. & TOINT, P., 15 Feb 2023, In: Computational Optimization and Applications. 84, 2, p. 573-607 35 p.
Research output: Contribution to journal › Article › peer-review

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20 Downloads (Pure)

2 Active

Complexity in nonlinear optimization
Toint, P. (CoI), Gould, N. I. M. (CoI) & Cartis, C. (CoI)
1/11/08 → …
Project: Research
ADALGOPT: ADALGOPT - Advanced algorithms in nonlinear optimization
Sartenaer, A. (CoI) & Toint, P. (CoI)
1/01/87 → …
Project: Research Axis

1 Participation in workshop, seminar, course

ALGOPT2024 workshop on Algorithmic Optimization
Toint, P. (Contributor)
27 Aug 2024 → 30 Aug 2024
Activity: Participating in or organising an event types › Participation in workshop, seminar, course

Cite this

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title = "Complexity of Adagrad and other first-order methods for nonconvex optimization problems with bounds constraints",

abstract = "A parametric class of trust-region algorithms for constrained nonconvex optimization is analyzed, where the objective function is never computed. By defining appropriate first-order stationarity criteria, we are able to extend the Adagrad method to the newly considered problem and retrieve the standard complexity rate of the projected gradient method that uses both the gradient and objective function values. Furthermore, we propose an additional iteration-dependent scaling with slightly inferior theoretical guarantees. In both cases, the bounds are essentially sharp, and curvature information can be used to compute the stepsize. Initial experimental results for noisy bound-constrained instances illustrate the benefits of the objective-free approach.",

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N2 - A parametric class of trust-region algorithms for constrained nonconvex optimization is analyzed, where the objective function is never computed. By defining appropriate first-order stationarity criteria, we are able to extend the Adagrad method to the newly considered problem and retrieve the standard complexity rate of the projected gradient method that uses both the gradient and objective function values. Furthermore, we propose an additional iteration-dependent scaling with slightly inferior theoretical guarantees. In both cases, the bounds are essentially sharp, and curvature information can be used to compute the stepsize. Initial experimental results for noisy bound-constrained instances illustrate the benefits of the objective-free approach.

AB - A parametric class of trust-region algorithms for constrained nonconvex optimization is analyzed, where the objective function is never computed. By defining appropriate first-order stationarity criteria, we are able to extend the Adagrad method to the newly considered problem and retrieve the standard complexity rate of the projected gradient method that uses both the gradient and objective function values. Furthermore, we propose an additional iteration-dependent scaling with slightly inferior theoretical guarantees. In both cases, the bounds are essentially sharp, and curvature information can be used to compute the stepsize. Initial experimental results for noisy bound-constrained instances illustrate the benefits of the objective-free approach.

M3 - Working paper

VL - 2406.15793

BT - Complexity of Adagrad and other first-order methods for nonconvex optimization problems with bounds constraints

PB - Arxiv

ER -

Complexity of Adagrad and other first-order methods for nonconvex optimization problems with bounds constraints

Abstract

Access to Document

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Research output

A Stochastic Objective-Function-Free Adaptive Regularization Method with Optimal Complexity

Divergence of the ADAM algorithm with fixed-stepsize: a (very) simple example

OFFO minimization algorithms for second-order optimality and their complexity

Projects

Complexity in nonlinear optimization

ADALGOPT: ADALGOPT - Advanced algorithms in nonlinear optimization

Activities

ALGOPT2024 workshop on Algorithmic Optimization

Cite this