Finding Robust Solutions to Stable Marriage
Abstract
We study the notion of robustness in stable matching problems. We first define robustness by introducing (a,b)-supermatches. An $(a,b)$-supermatch is a stable matching in which if $a$ pairs break up it is possible to find another stable matching by changing the partners of those $a$ pairs and at most $b$ other pairs. In this context, we define the most robust stable matching as a $(1,b)$-supermatch where b is minimum. We show that checking whether a given stable matching is a $(1,b)$-supermatch can be done in polynomial time. Next, we use this procedure to design a constraint programming model, a local search approach, and a genetic algorithm to find the most robust stable matching. Our empirical evaluation on large instances show that local search outperforms the other approaches.
Cite
Text
Genc et al. "Finding Robust Solutions to Stable Marriage." International Joint Conference on Artificial Intelligence, 2017. doi:10.24963/IJCAI.2017/88Markdown
[Genc et al. "Finding Robust Solutions to Stable Marriage." International Joint Conference on Artificial Intelligence, 2017.](https://mlanthology.org/ijcai/2017/genc2017ijcai-finding/) doi:10.24963/IJCAI.2017/88BibTeX
@inproceedings{genc2017ijcai-finding,
title = {{Finding Robust Solutions to Stable Marriage}},
author = {Genc, Begum and Siala, Mohamed and O'Sullivan, Barry and Simonin, Gilles},
booktitle = {International Joint Conference on Artificial Intelligence},
year = {2017},
pages = {631-637},
doi = {10.24963/IJCAI.2017/88},
url = {https://mlanthology.org/ijcai/2017/genc2017ijcai-finding/}
}