Approximation Algorithm for Minimum $p$ Union Under a Geometric Setting Article Swipe

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Combinatorics Hypergraph Mathematics Unit (ring theory) Square (algebra) Integer (computer science) Unit square Set (abstract data type) Plane (geometry) Approximation algorithm Value (mathematics) Discrete mathematics Algorithm Geometry Computer science Statistics Programming language Mathematics education

Yingli Ran , Zhao Zhang ·

YOU? · · 2022 · Open Access · · DOI: https://doi.org/10.48550/arxiv.2208.14264 · OA: W4293998607

In a minimum $p$ union problem (Min$p$U), given a hypergraph $G=(V,E)$ and an integer $p$, the goal is to find a set of $p$ hyperedges $E'\subseteq E$ such that the number of vertices covered by $E'$ (that is $|\bigcup_{e\in E'}e|$) is minimized. It was known that Min$p$U is at least as hard as the densest $k$-subgraph problem. A question is: how about the problem in some geometric settings? In this paper, we consider the unit square Min$p$U problem (Min$p$U-US) in which $V$ is a set of points on the plane, and each hyperedge of $E$ consists of a set of points in a unit square. A $(\frac{1}{1+\varepsilon},4)$-bicriteria approximation algorithm is presented, that is, the algorithm finds at least $\frac{p}{1+\varepsilon}$ unit squares covering at most $4opt$ points, where $opt$ is the optimal value for the Min$p$U-US instance (the minimum number of points that can be covered by $p$ unit squares).