English

First Steps Towards a Runtime Analysis When Starting With a Good Solution

Neural and Evolutionary Computing 2025-11-14 v3

Abstract

The mathematical runtime analysis of evolutionary algorithms traditionally regards the time an algorithm needs to find a solution of a certain quality when initialized with a random population. In practical applications it may be possible to guess solutions that are better than random ones. We start a mathematical runtime analysis for such situations. We observe that different algorithms profit to a very different degree from a better initialization. We also show that the optimal parameterization of the algorithm can depend strongly on the quality of the initial solutions. To overcome this difficulty, self-adjusting and randomized heavy-tailed parameter choices can be profitable. Finally, we observe a larger gap between the performance of the best evolutionary algorithm we found and the corresponding black-box complexity. This could suggest that evolutionary algorithms better exploiting good initial solutions are still to be found. These first findings stem from analyzing the performance of the (1+1)(1+1) evolutionary algorithm and the static, self-adjusting, and heavy-tailed (1+(λ,λ))(1 + (\lambda,\lambda)) GA on the OneMax benchmark. We are optimistic that the question how to profit from good initial solutions is interesting beyond these first examples.

Keywords

Cite

@article{arxiv.2006.12161,
  title  = {First Steps Towards a Runtime Analysis When Starting With a Good Solution},
  author = {Denis Antipov and Maxim Buzdalov and Benjamin Doerr},
  journal= {arXiv preprint arXiv:2006.12161},
  year   = {2025}
}

Comments

The extended version of the PPSN 2020 conference paper

R2 v1 2026-06-23T16:30:56.421Z