First Steps Towards a Runtime Analysis When Starting With a Good Solution
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 evolutionary algorithm and the static, self-adjusting, and heavy-tailed GA on the OneMax benchmark. We are optimistic that the question how to profit from good initial solutions is interesting beyond these first examples.
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