Obstructions to faster diameter computation: Asteroidal sets

International Symposium on Parameterized and Exact Computation Pub Date : 2022-09-26 DOI:10.48550/arXiv.2209.12438

G. Ducoffe

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Abstract

An extremity is a vertex such that the removal of its closed neighbourhood does not increase the number of connected components. Let $Ext_{\alpha}$ be the class of all connected graphs whose quotient graph obtained from modular decomposition contains no more than $\alpha$ pairwise nonadjacent extremities. Our main contributions are as follows. First, we prove that the diameter of every $m$-edge graph in $Ext_{\alpha}$ can be computed in deterministic ${\cal O}(\alpha^3 m^{3/2})$ time. We then improve the runtime to linear for all graphs with bounded clique-number. Furthermore, we can compute an additive $+1$-approximation of all vertex eccentricities in deterministic ${\cal O}(\alpha^2 m)$ time. This is in sharp contrast with general $m$-edge graphs for which, under the Strong Exponential Time Hypothesis (SETH), one cannot compute the diameter in ${\cal O}(m^{2-\epsilon})$ time for any $\epsilon>0$. As important special cases of our main result, we derive an ${\cal O}(m^{3/2})$-time algorithm for exact diameter computation within dominating pair graphs of diameter at least six, and an ${\cal O}(k^3m^{3/2})$-time algorithm for this problem on graphs of asteroidal number at most $k$. We end up presenting an improved algorithm for chordal graphs of bounded asteroidal number, and a partial extension of our results to the larger class of all graphs with a dominating target of bounded cardinality. Our time upper bounds in the paper are shown to be essentially optimal under plausible complexity assumptions.

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阻碍更快的直径计算:小行星集合

端点是这样一个顶点，它的封闭邻域的移除不会增加连接分量的数量。设$Ext_{\alpha}$为由模分解得到的商图包含不超过$\alpha$对非相邻极值的所有连通图的类。我们的主要贡献如下。首先，我们证明了$Ext_{\alpha}$中每个$m$ -边图的直径可以在确定的${\cal O}(\alpha^3 m^{3/2})$时间内计算出来。然后，我们将所有具有有界团数的图的运行时间改进为线性。此外，我们可以在确定的${\cal O}(\alpha^2 m)$时间内计算所有顶点偏心率的加性$+1$近似。这与一般的$m$ -边图形成鲜明对比，在强指数时间假设(SETH)下，人们无法计算任何$\epsilon>0$在${\cal O}(m^{2-\epsilon})$时间内的直径。作为我们主要结果的重要特例，我们导出了在直径至少为6的主导对图内精确直径计算的${\cal O}(m^{3/2})$时间算法，以及在小行星数最多为$k$的图上该问题的${\cal O}(k^3m^{3/2})$时间算法。我们最终提出了一种改进的有界小行星数弦图算法，并将我们的结果部分扩展到所有以有界基数为主要目标的更大的图类。在合理的复杂性假设下，本文的时间上界是最优的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International Symposium on Parameterized and Exact Computation

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