Mixed integer programming with convex/concave constraints: Fixed-parameter tractability and applications to multicovering and voting

Bredereck, Robert; Faliszewski, Piotr; Niedermeier, Rolf; Skowron, Piotr; Talmon, Nimrod

doi:10.1016/j.tcs.2020.01.017

Cited by 20 publications

(21 citation statements)

References 53 publications

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“…We will use the classic result of Lenstra (1983) which says that an integer linear program (ILP) can be solved in FPT time with respect to the number of integer variables. We will also use a recent result of Bredereck et al (2017) who proved that one can apply concave/convex transformations of certain variables in an ILP, and that such a modified program can be still solved in an FPT time. We construct an ILP as follows.…”

Section: Fair Knapsackmentioning

confidence: 99%

“…The above program uses concave transformations (logarithms) for the maximized expression, and convex transformations (functions f z ) in the left-hand sides of the constraints, so we can use the result of Bredereck et al (2017) and claim that this program can be solved in an FPT time with respect to the number of integer variables. This completes the proof.…”

Section: Fair Knapsackmentioning

confidence: 99%

See 1 more Smart Citation

Fair Knapsack

Fluschnik

Skowron

Triphaus

et al. 2019

AAAI

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We study the following multiagent variant of the knapsack problem. We are given a set of items, a set of voters, and a value of the budget; each item is endowed with a cost and each voter assigns to each item a certain value. The goal is to select a subset of items with the total cost not exceeding the budget, in a way that is consistent with the voters’ preferences. Since the preferences of the voters over the items can vary significantly, we need a way of aggregating these preferences, in order to select the socially best valid knapsack. We study three approaches to aggregating voters’ preferences, which are motivated by the literature on multiwinner elections and fair allocation. This way we introduce the concepts of individually best, diverse, and fair knapsack. We study the computational complexity (including parameterized complexity, and complexity under restricted domains) of the aforementioned multiagent variants of knapsack.

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Section: Fair Knapsackmentioning

confidence: 99%

Section: Fair Knapsackmentioning

confidence: 99%

Fair Knapsack

Fluschnik

Skowron

Triphaus

et al. 2019

AAAI

Self Cite

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“…The reason is that this can be reduced to an FPT version of the SET MULTI-COVER. Proposition 1 (implied by [Bredereck et al, 2020]). CAV-1 and CDV-1 can be solved in polynomial time for Unconditional Minisum if the domain size of each issue is constant.…”

Section: Controlling Votersmentioning

confidence: 99%

Winner Determination and Strategic Control in Conditional Approval Voting

Markakis

Papasotiropoulos

2021

Proceedings of the Thirtieth International Joint Conference on Artificial Intelligence

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Our work focuses on a generalization of the classic Minisum approval voting rule, introduced by Barrot and Lang (2016), and referred to as Conditional Minisum (CMS), for multi-issue elections. Although the CMS rule provides much higher levels of expressiveness, this comes at the expense of increased computational complexity. In this work, we study further the issue of efficient algorithms for CMS, and we identify the condition of bounded treewidth (of an appropriate graph that emerges from the provided ballots), as the necessary and sufficient condition for polynomial algorithms, under common complexity assumptions. Additionally we investigate the complexity of problems related to the strategic control of such elections by the possibility of adding or deleting either voters or alternatives. We exhibit that in most variants of these problems, CMS is resistant against control.

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“…Additionally, let us consider the Multiset Multicover Problem. This problem has received quite a lot of attention in recent papers [5,6,17,24,25,26]. An exact (c max + 1) n • poly(φ)-complexity algorithm for this problem, parameterized by the universe size n and the maximum coverage constraint number c max , is given in [24,25].…”

Section: The Problems Under Consideration and Motivation Of This Papermentioning

confidence: 99%