Parameterized Complexity of Submodular Minimization under Uncertainty
Abstract
This paper studies the computational complexity of a robust variant of a two-stage submodular minimization problem that we call Robust Submodular Minimizer. In this problem, we are given submodular functions~ over a set family~, which represent possible scenarios in the future when we will need to find an optimal solution for one of these scenarios, i.e., a minimizer for one of the functions. The present task is to find a set that is close to \emph{some} optimal solution for each in the sense that some minimizer of~ can be obtained from by adding/removing at most elements for a given integer . The main contribution of this paper is to provide a complete computational map of this problem with respect to parameters~ and~, which reveals a tight complexity threshold for both parameters: (1) Robust Submodular Minimizer can be solved in polynomial time when , but is NP-hard if is a constant with .(2)Robust Submodular Minimizer can be solved in polynomial time when , but is NP-hard if is a constant with . (3) Robust Submodular Minimizer is fixed-parameter tractable when parameterized by~. We also show that if some submodular function has a polynomial number of minimizers, then the problem becomes fixed-parameter tractable when parameterized by . On the other hand, the problem remains -hard parameterized by even if each function has at most~ minimizers. We remark that all our hardness results hold even if each submodular function is given by a cut function of a directed graph.
Cite
@article{arxiv.2404.07516,
title = {Parameterized Complexity of Submodular Minimization under Uncertainty},
author = {Naonori Kakimura and Ildikó Schlotter},
journal= {arXiv preprint arXiv:2404.07516},
year = {2024}
}