{"title":"Achieving Maximin Share and EFX/EF1 Guarantees Simultaneously","authors":"Hannaneh Akrami, Nidhi Rathi","doi":"arxiv-2409.01963","DOIUrl":null,"url":null,"abstract":"We study the problem of computing \\emph{fair} divisions of a set of\nindivisible goods among agents with \\emph{additive} valuations. For the past\nmany decades, the literature has explored various notions of fairness, that can\nbe primarily seen as either having \\emph{envy-based} or \\emph{share-based}\nlens. For the discrete setting of resource-allocation problems, \\emph{envy-free\nup to any good} (EFX) and \\emph{maximin share} (MMS) are widely considered as\nthe flag-bearers of fairness notions in the above two categories, thereby\ncapturing different aspects of fairness herein. Due to lack of existence\nresults of these notions and the fact that a good approximation of EFX or MMS\ndoes not imply particularly strong guarantees of the other, it becomes\nimportant to understand the compatibility of EFX and MMS allocations with one\nanother. In this work, we identify a novel way to simultaneously achieve MMS\nguarantees with EFX/EF1 notions of fairness, while beating the best known\napproximation factors [Chaudhury et al., 2021, Amanatidis et al., 2020]. Our\nmain contribution is to constructively prove the existence of (i) a partial\nallocation that is both $2/3$-MMS and EFX, and (ii) a complete allocation that\nis both $2/3$-MMS and EF1. Our algorithms run in pseudo-polynomial time if the\napproximation factor for MMS is relaxed to $2/3-\\varepsilon$ for any constant\n$\\varepsilon > 0$ and in polynomial time if, in addition, the EFX (or EF1)\nguarantee is relaxed to $(1-\\delta)$-EFX (or $(1-\\delta)$-EF1) for any constant\n$\\delta>0$. In particular, we improve from the best approximation factor known\nprior to our work, which computes partial allocations that are $1/2$-MMS and\nEFX in pseudo-polynomial time [Chaudhury et al., 2021].","PeriodicalId":501316,"journal":{"name":"arXiv - CS - Computer Science and Game Theory","volume":"30 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-09-03","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv - CS - Computer Science and Game Theory","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/arxiv-2409.01963","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
We study the problem of computing \emph{fair} divisions of a set of
indivisible goods among agents with \emph{additive} valuations. For the past
many decades, the literature has explored various notions of fairness, that can
be primarily seen as either having \emph{envy-based} or \emph{share-based}
lens. For the discrete setting of resource-allocation problems, \emph{envy-free
up to any good} (EFX) and \emph{maximin share} (MMS) are widely considered as
the flag-bearers of fairness notions in the above two categories, thereby
capturing different aspects of fairness herein. Due to lack of existence
results of these notions and the fact that a good approximation of EFX or MMS
does not imply particularly strong guarantees of the other, it becomes
important to understand the compatibility of EFX and MMS allocations with one
another. In this work, we identify a novel way to simultaneously achieve MMS
guarantees with EFX/EF1 notions of fairness, while beating the best known
approximation factors [Chaudhury et al., 2021, Amanatidis et al., 2020]. Our
main contribution is to constructively prove the existence of (i) a partial
allocation that is both $2/3$-MMS and EFX, and (ii) a complete allocation that
is both $2/3$-MMS and EF1. Our algorithms run in pseudo-polynomial time if the
approximation factor for MMS is relaxed to $2/3-\varepsilon$ for any constant
$\varepsilon > 0$ and in polynomial time if, in addition, the EFX (or EF1)
guarantee is relaxed to $(1-\delta)$-EFX (or $(1-\delta)$-EF1) for any constant
$\delta>0$. In particular, we improve from the best approximation factor known
prior to our work, which computes partial allocations that are $1/2$-MMS and
EFX in pseudo-polynomial time [Chaudhury et al., 2021].