图上公平划分的精细复杂性分析

IF 2 3区计算机科学 Q3 AUTOMATION & CONTROL SYSTEMS

Autonomous Agents and Multi-Agent Systems Pub Date : 2022-12-28 DOI:10.1007/s10458-022-09594-2

Niclas Boehmer, Tomohiro Koana, Rolf Niedermeier

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引用次数: 3

摘要

我们研究了Stoica等人最近提出的NP难公平连通划分问题。[AAMAS 2020]：将顶点着色图划分为k个连通分量（随后称为区域），以便在每个区域中，最频繁的颜色最多比第二频繁的颜色出现给定次数。公平连接区域划分是由各种现实世界场景驱动的，在这些场景中，由网络中的节点一对一表示的不同类型的代理必须被划分为不相交的区域。在这里，人们努力争取“公平的地区”，而不是任何类型在任何地区占主导地位。这是为了防止某些政党的种族隔离或政治统治。我们对公平连通划分的（参数化的）计算复杂性进行了细粒度分析。特别地，我们证明了它在路径、循环、恒星和毛虫上是多项式时间可解的，但在树上已经变成了NP难解。受后一个负面结果的启发，我们对各种图参数进行了参数化复杂性分析，包括树宽和特定问题的参数，包括颜色和区域的数量。我们获得了相应的参数化复杂度景观的丰富多样、接近完整的图片（即，沿着复杂度类别FPT、XP、W[1]-硬和准NP-硬的分类）。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

A refined complexity analysis of fair districting over graphs

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A refined complexity analysis of fair districting over graphs

We study the NP-hard Fair Connected Districting problem recently proposed by Stoica et al. [AAMAS 2020]: Partition a vertex-colored graph into k connected components (subsequently referred to as districts) so that in every district the most frequent color occurs at most a given number of times more often than the second most frequent color. Fair Connected Districting is motivated by various real-world scenarios where agents of different types, which are one-to-one represented by nodes in a network, have to be partitioned into disjoint districts. Herein, one strives for “fair districts” without any type being in a dominating majority in any of the districts. This is to e.g. prevent segregation or political domination of some political party. We conduct a fine-grained analysis of the (parameterized) computational complexity of Fair Connected Districting. In particular, we prove that it is polynomial-time solvable on paths, cycles, stars, and caterpillars, but already becomes NP-hard on trees. Motivated by the latter negative result, we perform a parameterized complexity analysis with respect to various graph parameters including treewidth, and problem-specific parameters, including, the numbers of colors and districts. We obtain a rich and diverse, close to complete picture of the corresponding parameterized complexity landscape (that is, a classification along the complexity classes FPT, XP, W[1]-hard, and para-NP-hard).

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来源期刊

Autonomous Agents and Multi-Agent Systems 工程技术-计算机：人工智能

CiteScore

6.00

自引率

5.30%

发文量

审稿时长

>12 weeks

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