Polynomial algorithms for p-dispersion problems in a planar Pareto Front
Abstract
In this paper, p-dispersion problems are studied to select representative points from a large 2D Pareto Front (PF), solution of bi-objective optimization. Four standard p-dispersion variants are considered. A novel variant, Max-Sum-Neighbor p-dispersion, is introduced for the specific case of a 2D PF. Firstly, -dispersion and -dispersion problems are proven solvable in time in a 2D PF. Secondly, dynamic programming algorithms are designed for three p-dispersion variants, proving polynomial complexities in a 2D PF. Max-min p-dispersion is solvable in time and memory space. Max-Sum-Neighbor p-dispersion is proven solvable in time and{} space. Max-Sum-min p-dispersion is solvable in time and space, this complexity holds also in 1D, proving for the first time that Max-Sum-min p-dispersion is polynomial in 1D. Furthermore, properties of these algorithms are discussed for an efficient implementation {and for a practical application inside bi-objective meta-heuristics.
Cite
@article{arxiv.2002.11830,
title = {Polynomial algorithms for p-dispersion problems in a planar Pareto Front},
author = {Nicolas Dupin},
journal= {arXiv preprint arXiv:2002.11830},
year = {2023}
}