English

Gradient methods for convex minimization: better rates under weaker conditions

Optimization and Control 2013-09-10 v2 Information Theory math.IT Numerical Analysis

Abstract

The convergence behavior of gradient methods for minimizing convex differentiable functions is one of the core questions in convex optimization. This paper shows that their well-known complexities can be achieved under conditions weaker than the commonly accepted ones. We relax the common gradient Lipschitz-continuity condition and strong convexity condition to ones that hold only over certain line segments. Specifically, we establish complexities O(Rϵ)O(\frac{R}{\epsilon}) and O(Rϵ)O(\sqrt{\frac{R}{\epsilon}}) for the ordinary and accelerate gradient methods, respectively, assuming that f\nabla f is Lipschitz continuous with constant RR over the line segment joining xx and x1Rfx-\frac{1}{R}\nabla f for each x\domfx\in\dom f. Then we improve them to O(Rνlog(1ϵ))O(\frac{R}{\nu}\log(\frac{1}{\epsilon})) and O(Rνlog(1ϵ))O(\sqrt{\frac{R}{\nu}}\log(\frac{1}{\epsilon})) for function ff that also satisfies the secant inequality  <f(x),xx >νxx2\ < \nabla f(x), x- x^*\ > \ge \nu\|x-x^*\|^2 for each x\domfx\in \dom f and its projection xx^* to the minimizer set of ff. The secant condition is also shown to be necessary for the geometric decay of solution error. Not only are the relaxed conditions met by more functions, the restrictions give smaller RR and larger ν\nu than they are without the restrictions and thus lead to better complexity bounds. We apply these results to sparse optimization and demonstrate a faster algorithm.

Keywords

Cite

@article{arxiv.1303.4645,
  title  = {Gradient methods for convex minimization: better rates under weaker conditions},
  author = {Hui Zhang and Wotao Yin},
  journal= {arXiv preprint arXiv:1303.4645},
  year   = {2013}
}

Comments

20 pages, 4 figures, typos are corrected, Theorem 2 is new

R2 v1 2026-06-21T23:44:31.732Z