English

Exploiting higher-order derivatives in convex optimization methods

Optimization and Control 2024-03-13 v3

Abstract

Exploiting higher-order derivatives in convex optimization is known at least since 1970's. In each iteration higher-order (also called tensor) methods minimize a regularized Taylor expansion of the objective function, which leads to faster convergence rates if the corresponding higher-order derivative is Lipschitz-continuous. Recently a series of lower iteration complexity bounds for such methods were proved, and a gap between upper an lower complexity bounds was revealed. Moreover, it was shown that such methods can be implementable since the appropriately regularized Taylor expansion of a convex function is also convex and, thus, can be minimized in polynomial time. Only very recently an algorithm with optimal convergence rate 1/k(3p+1)/21/k^{(3p+1)/2} was proposed for minimizing convex functions with Lipschitz pp-th derivative. For convex functions with Lipschitz third derivative, these developments allowed to propose a second-order method with convergence rate 1/k51/k^5, which is faster than the rate 1/k3.51/k^{3.5} of existing second-order methods.

Keywords

Cite

@article{arxiv.2208.13190,
  title  = {Exploiting higher-order derivatives in convex optimization methods},
  author = {Dmitry Kamzolov and Alexander Gasnikov and Pavel Dvurechensky and Artem Agafonov and Martin Takáč},
  journal= {arXiv preprint arXiv:2208.13190},
  year   = {2024}
}
R2 v1 2026-06-25T02:02:09.806Z