M. Balko, S. Chaplick, R. Ganian, Siddharth Gupta, M. Hoffmann, P. Valtr, A. Wolff
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Wolff\",\"doi\":\"10.48550/arXiv.2206.15414\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"An obstacle representation of a graph $G$ consists of a set of pairwise disjoint simply-connected closed regions and a one-to-one mapping of the vertices of $G$ to points such that two vertices are adjacent in $G$ if and only if the line segment connecting the two corresponding points does not intersect any obstacle. The obstacle number of a graph is the smallest number of obstacles in an obstacle representation of the graph in the plane such that all obstacles are simple polygons. It is known that the obstacle number of each $n$-vertex graph is $O(n \\\\log n)$ [Balko, Cibulka, and Valtr, 2018] and that there are $n$-vertex graphs whose obstacle number is $\\\\Omega(n/(\\\\log\\\\log n)^2)$ [Dujmovi\\\\'c and Morin, 2015]. We improve this lower bound to $\\\\Omega(n/\\\\log\\\\log n)$ for simple polygons and to $\\\\Omega(n)$ for convex polygons. 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引用次数: 3
摘要
图$G$的障碍物表示由一组成对不相交的单连通封闭区域和$G$的顶点到点的一对一映射组成,当且仅当连接两个对应点的线段不与任何障碍物相交时,$G$中的两个顶点相邻。图的障碍物数是平面上图的障碍物表示中障碍物的最小数量,使得所有障碍物都是简单多边形。已知每个$n$ -顶点图的障碍数为$O(n \log n)$ [Balko, Cibulka, and Valtr, 2018],存在障碍数为$\Omega(n/(\log\log n)^2)$的$n$ -顶点图[dujmovovic and Morin, 2015]。我们将简单多边形的下界改进为$\Omega(n/\log\log n)$,凸多边形的下界改进为$\Omega(n)$。为了得到这些更强的边界,我们改进了已知的$n$ -顶点图有界障碍数的估计,解决了dujmovovic和Morin的一个猜想。我们还表明,如果一些$n$顶点图的绘图作为输入的一部分给出,那么对于一些绘图$\Omega(n^2)$障碍物需要将它们转换为图形的障碍物表示。在一些情况下,我们的界是渐近紧的。我们用两个复杂度结果来补充这些组合界。首先,我们证明了在$G$的顶点覆盖数中计算图$G$的障碍数是固定参数可处理的。其次,我们证明,给定一个图$G$和一个简单的多边形$P$,决定$G$是否允许使用$P$作为唯一障碍物的障碍物表示是np困难的。
An obstacle representation of a graph $G$ consists of a set of pairwise disjoint simply-connected closed regions and a one-to-one mapping of the vertices of $G$ to points such that two vertices are adjacent in $G$ if and only if the line segment connecting the two corresponding points does not intersect any obstacle. The obstacle number of a graph is the smallest number of obstacles in an obstacle representation of the graph in the plane such that all obstacles are simple polygons. It is known that the obstacle number of each $n$-vertex graph is $O(n \log n)$ [Balko, Cibulka, and Valtr, 2018] and that there are $n$-vertex graphs whose obstacle number is $\Omega(n/(\log\log n)^2)$ [Dujmovi\'c and Morin, 2015]. We improve this lower bound to $\Omega(n/\log\log n)$ for simple polygons and to $\Omega(n)$ for convex polygons. To obtain these stronger bounds, we improve known estimates on the number of $n$-vertex graphs with bounded obstacle number, solving a conjecture by Dujmovi\'c and Morin. We also show that if the drawing of some $n$-vertex graph is given as part of the input, then for some drawings $\Omega(n^2)$ obstacles are required to turn them into an obstacle representation of the graph. Our bounds are asymptotically tight in several instances. We complement these combinatorial bounds by two complexity results. First, we show that computing the obstacle number of a graph $G$ is fixed-parameter tractable in the vertex cover number of $G$. Second, we show that, given a graph $G$ and a simple polygon $P$, it is NP-hard to decide whether $G$ admits an obstacle representation using $P$ as the only obstacle.
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