English

Improving Simulated Annealing through Derandomization

Computation 2016-09-06 v4 Numerical Analysis Optimization and Control

Abstract

We propose and study a version of simulated annealing (SA) on continuous state spaces based on (t,s)R(t,s)_R-sequences. The parameter RNˉR\in\bar{\mathbb{N}} regulates the degree of randomness of the input sequence, with the case R=0R=0 corresponding to IID uniform random numbers and the limiting case R=R=\infty to (t,s)(t,s)-sequences. Our main result, obtained for rectangular domains, shows that the resulting optimization method, which we refer to as QMC-SA, converges almost surely to the global optimum of the objective function φ\varphi for any RNR\in\mathbb{N}. When φ\varphi is univariate, we are in addition able to show that the completely deterministic version of QMC-SA is convergent. A key property of these results is that they do not require objective-dependent conditions on the cooling schedule. As a corollary of our theoretical analysis, we provide a new almost sure convergence result for SA which shares this property under minimal assumptions on φ\varphi. We further explain how our results in fact apply to a broader class of optimization methods including for example threshold accepting, for which to our knowledge no convergence results currently exist. We finally illustrate the superiority of QMC-SA over SA algorithms in a numerical study.

Keywords

Cite

@article{arxiv.1505.03173,
  title  = {Improving Simulated Annealing through Derandomization},
  author = {Mathieu Gerber and Luke Bornn},
  journal= {arXiv preprint arXiv:1505.03173},
  year   = {2016}
}

Comments

33 pages, 4 figures (final version)

R2 v1 2026-06-22T09:33:02.756Z