An outer approximation algorithm for generating the Edgeworth–Pareto hull of multi-objective mixed-integer linear programming problems

IF 0.9 4区 数学 Q3 MATHEMATICS, APPLIED
Fritz Bökler, Sophie N. Parragh, Markus Sinnl, Fabien Tricoire
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引用次数: 0

Abstract

In this paper, we present an outer approximation algorithm for computing the Edgeworth–Pareto hull of multi-objective mixed-integer linear programming problems (MOMILPs). It produces the extreme points (i.e., the vertices) as well as the facets of the Edgeworth–Pareto hull. We note that these extreme points are the extreme supported non-dominated points of a MOMILP. We also show how to extend the concept of geometric duality for multi-objective linear programming problems to the Edgeworth–Pareto hull of MOMILPs and use this extension to develop the algorithm. The algorithm relies on a novel oracle that solves single-objective weighted-sum problems and we show that the required number of oracle calls is polynomial in the number of facets of the convex hull of the extreme supported non-dominated points in the case of MOMILPs. Thus, for MOMILPs for which the weighted-sum problem is solvable in polynomial time, the facets can be computed with incremental-polynomial delay—a result that was formerly only known for the computation of extreme supported non-dominated points. Our algorithm can be an attractive option to compute lower bound sets within multi-objective branch-and-bound algorithms for solving MOMILPs. This is for several reasons as (i) the algorithm starts from a trivial valid lower bound set then iteratively improves it, thus at any iteration of the algorithm a lower bound set is available; (ii) the algorithm also produces efficient solutions (i.e., solutions in the decision space); (iii) in any iteration of the algorithm, a relaxation of the MOMILP can be solved, and the obtained points and facets still provide a valid lower bound set. Moreover, for the special case of multi-objective linear programming problems, the algorithm solves the problem to global optimality. A computational study on a set of benchmark instances from the literature is provided.

Abstract Image

生成多目标混合整数线性规划问题埃奇沃斯-帕雷托体的外近似算法
本文提出了一种计算多目标混合整数线性规划问题(MOMILPs)埃奇沃思-帕雷托壳的外近似算法。该算法能生成极值点(即顶点)以及埃奇沃斯-帕雷托壳的面。我们注意到,这些极值点就是 MOMILP 的极值支持非支配点。我们还展示了如何将多目标线性规划问题的几何对偶性概念扩展到 MOMILP 的 Edgeworth-Pareto 体,并利用这一扩展来开发算法。我们证明,在 MOMILPs 的情况下,所需的神谕调用次数与极值支持非支配点凸面的面数成多项式关系。因此,对于加权求和问题可在多项式时间内求解的 MOMILPs,可以用增量-多项式延迟计算面--这一结果以前只在计算极值支持的非支配点时才为人所知。在求解 MOMILPs 的多目标分支边界算法中,我们的算法是计算下界集的一个极具吸引力的选择。这是由于以下几个原因:(i) 算法从一个微不足道的有效下界集开始,然后迭代改进,因此在算法的任何一次迭代中,都有一个下界集可用;(ii) 算法还能产生高效解(即决策空间中的解);(iii) 在算法的任何一次迭代中,都可以求解 MOMILP 的松弛,所得到的点和面仍能提供一个有效的下界集。此外,对于多目标线性规划问题的特殊情况,该算法可以求解全局最优问题。本文还对文献中的一组基准实例进行了计算研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
1.90
自引率
0.00%
发文量
36
审稿时长
>12 weeks
期刊介绍: This peer reviewed journal publishes original and high-quality articles on important mathematical and computational aspects of operations research, in particular in the areas of continuous and discrete mathematical optimization, stochastics, and game theory. Theoretically oriented papers are supposed to include explicit motivations of assumptions and results, while application oriented papers need to contain substantial mathematical contributions. Suggestions for algorithms should be accompanied with numerical evidence for their superiority over state-of-the-art methods. Articles must be of interest for a large audience in operations research, written in clear and correct English, and typeset in LaTeX. A special section contains invited tutorial papers on advanced mathematical or computational aspects of operations research, aiming at making such methodologies accessible for a wider audience. All papers are refereed. The emphasis is on originality, quality, and importance.
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