Abstract
Deterministic global optimization algorithms like Piyavskii–Shubert, direct, ego and many more, have a recognized standing, for problems with many local optima. Although many single objective optimization algorithms have been extended to multiple objectives, completely deterministic algorithms for nonlinear problems with guarantees of convergence to global Pareto optimality are still missing. For instance, deterministic algorithms usually make use of some form of scalarization, which may lead to incomplete representations of the Pareto optimal set. Thus, all global Pareto optima may not be obtained, especially in nonconvex cases. On the other hand, algorithms attempting to produce representations of the globally Pareto optimal set are usually based on heuristics. We analyze the concept of global convergence for multiobjective optimization algorithms and propose a convergence criterion based on the Hausdorff distance in the decision space. Under this light, we consider the well-known global optimization algorithm direct, analyze the available algorithms in the literature that extend direct to multiple objectives and discuss possible alternatives. In particular, we propose a novel definition for the notion of potential Pareto optimality extending the notion of potential optimality defined in direct. We also discuss its advantages and disadvantages when compared with algorithms existing in the literature.
Highlights
We consider the class of exact global optimization algorithms and their possible extensions to the multiobjective optimization case
We focus on direct because it has been recognized as an efficient algorithm for medium sized problems in the decision space
A set-wise global convergence is realized if a multiobjective optimization algorithm produces at every iteration n a candidate set Sn approximating the whole set of Pareto optima
Summary
We consider the class of exact (or deterministic) global optimization algorithms and their possible extensions to the multiobjective optimization case. The first contribution of this paper is clarifying the notion of global convergence in the case of multiple objectives on the basis of the Hausdorff distance between sets. The Euclidean distance between the exact minimizer and an approximated minimizer is the only necessary concept for establishing a convergence speed This is not the case in multiobjective optimization, where in the generic case, the set of Pareto optima is a (k − 1)-dimensional submanifold of the objective space, if k > 1 is the. 4, we discuss how the principles of direct have been extended to multiple objectives in the literature and analyze possible alternatives These ideas are collected and presented in the proposed multidirect algorithm.
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