Runtime Analyses of Multi-Objective Evolutionary Algorithms in the Presence of Noise
Runtime Analyses of Multi-Objective Evolutionary Algorithms in the Presence of Noise
Matthieu Dinot, Benjamin Doerr, Ulysse Hennebelle, Sebastian Will
Proceedings of the Thirty-Second International Joint Conference on Artificial Intelligence
Main Track. Pages 5549-5557.
https://doi.org/10.24963/ijcai.2023/616
In single-objective optimization, it is well known that evolutionary algorithms also without further adjustments can stand a certain amount of noise in the evaluation of the objective function. In contrast, this question is not at all understood for multi-objective optimization.
In this work, we conduct the first mathematical runtime analysis of a simple multi-objective evolutionary algorithm (MOEA) on a classic benchmark in the presence of noise in the objective function.
We prove that when bit-wise prior noise with rate p <= alpha/n, alpha a suitable constant, is present, the simple evolutionary multi-objective optimizer (SEMO) without any adjustments to cope with noise finds the Pareto front of the OneMinMax benchmark in time O(n^2 log n), just as in the case without noise. Given that the problem here is to arrive at a population consisting of n+1 individuals witnessing the Pareto front, this is a surprisingly strong robustness to noise (comparably simple evolutionary algorithms cannot optimize the single-objective OneMax problem in polynomial time when p = omega(log(n)/n)). Our proofs suggest that the strong robustness of the MOEA stems from its implicit diversity mechanism designed to enable it to compute a population covering the whole Pareto front.
Interestingly this result only holds when the objective value of a solution is determined only once and the algorithm from that point on works with this, possibly noisy, objective value. We prove that when all solutions are reevaluated in each iteration, then any noise rate p = omega(log(n)/n^2) leads to a super-polynomial runtime. This is very different from single-objective optimization, where it is generally preferred to reevaluate solutions whenever their fitness is important and where examples are known such that not reevaluating solutions can lead to catastrophic performance losses.
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