English

Block-proximal methods with spatially adapted acceleration

Optimization and Control 2020-02-13 v5 Numerical Analysis

Abstract

We study and develop (stochastic) primal--dual block-coordinate descent methods for convex problems based on the method due to Chambolle and Pock. Our methods have known convergence rates for the iterates and the ergodic gap: O(1/N2)O(1/N^2) if each block is strongly convex, O(1/N)O(1/N) if no convexity is present, and more generally a mixed rate O(1/N2)+O(1/N)O(1/N^2)+O(1/N) for strongly convex blocks, if only some blocks are strongly convex. Additional novelties of our methods include blockwise-adapted step lengths and acceleration, as well as the ability to update both the primal and dual variables randomly in blocks under a very light compatibility condition. In other words, these variants of our methods are doubly-stochastic. We test the proposed methods on various image processing problems, where we employ pixelwise-adapted acceleration.

Keywords

Cite

@article{arxiv.1609.07373,
  title  = {Block-proximal methods with spatially adapted acceleration},
  author = {Tuomo Valkonen},
  journal= {arXiv preprint arXiv:1609.07373},
  year   = {2020}
}
R2 v1 2026-06-22T15:59:17.672Z