Accelerated And Inexact Forward-Backward Algorithms

We propose a convergence analysis of accelerated forward-backward splitting methods for composite function minimization, when the proximity operator is not available in closed form, and can only be computed up to a certain precision. We prove that the 1/k(2) convergence rate for the function values can be achieved if the admissible errors are of a certain type and satisfy a sufficiently fast decay condition. Our analysis is based on the machinery of estimate sequences first introduced by Nesterov for the study of accelerated gradient descent algorithms. Furthermore, we give a global complexity analysis, taking into account the cost of computing admissible approximations of the proximal point. An experimental analysis is also presented.

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Accelerated And Inexact Forward-Backward Algorithms

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Towards Understanding Sharpness-Aware Minimization

Iterative pre-conditioning for expediting the distributed gradient-descent method: The case of linear least-squares problem

Faster One-Sample Stochastic Conditional Gradient Method for Composite Convex Minimization

Iterative pre-conditioning for expediting the distributed gradient-descent method: The case of linear least-squares problem

Towards Understanding Sharpness-Aware Minimization

Faster One-Sample Stochastic Conditional Gradient Method for Composite Convex Minimization