English

Nonsmooth optimization using Taylor-like models: error bounds, convergence, and termination criteria

Optimization and Control 2016-10-12 v1

Abstract

We consider optimization algorithms that successively minimize simple Taylor-like models of the objective function. Methods of Gauss-Newton type for minimizing the composition of a convex function and a smooth map are common examples. Our main result is an explicit relationship between the step-size of any such algorithm and the slope of the function at a nearby point. Consequently, we (1) show that the step-sizes can be reliably used to terminate the algorithm, (2) prove that as long as the step-sizes tend to zero, every limit point of the iterates is stationary, and (3) show that conditions, akin to classical quadratic growth, imply that the step-sizes linearly bound the distance of the iterates to the solution set. The latter so-called error bound property is typically used to establish linear (or faster) convergence guarantees. Analogous results hold when the step-size is replaced by the square root of the decrease in the model's value. We complete the paper with extensions to when the models are minimized only inexactly.

Keywords

Cite

@article{arxiv.1610.03446,
  title  = {Nonsmooth optimization using Taylor-like models: error bounds, convergence, and termination criteria},
  author = {Dmitriy Drusvyatskiy and Alexander D. Ioffe and Adrian S. Lewis},
  journal= {arXiv preprint arXiv:1610.03446},
  year   = {2016}
}

Comments

23 pages

R2 v1 2026-06-22T16:17:57.413Z