GLISp-r: a preference-based optimization algorithm with convergence guarantees

Abstract

AbstractPreference-based optimization algorithms are iterative procedures that seek the optimal calibration of a decision vector based only on comparisons between couples of different tunings. At each iteration, a human decision-maker expresses a preference between two calibrations (samples), highlighting which one, if any, is better than the other. The optimization procedure must use the observed preferences to find the tuning of the decision vector that is most preferred by the decision-maker, while also minimizing the number of comparisons. In this work, we formulate the preference-based optimization problem from a utility theory perspective. Then, we propose , an extension of a recent preference-based optimization procedure called . The latter uses a Radial Basis Function surrogate to describe the tastes of the decision-maker. Iteratively, proposes new samples to compare with the best calibration available by trading off exploitation of the surrogate model and exploration of the decision space. In , we propose a different criterion to use when looking for new candidate samples that is inspired by , a popular procedure in the black-box optimization framework. Compared to , is less likely to get stuck on local optima of the preference-based optimization problem. We motivate this claim theoretically, with a proof of global convergence, and empirically, by comparing the performances of and on several benchmark optimization problems.