Obstructions to faster diameter computation: Asteroidal sets

September 26, 2022 Β· Declared Dead Β· πŸ› International Symposium on Parameterized and Exact Computation

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Authors Guillaume Ducoffe arXiv ID 2209.12438 Category cs.DS: Data Structures & Algorithms Citations 1 Venue International Symposium on Parameterized and Exact Computation Last Checked 4 months ago
Abstract
An extremity is a vertex such that the removal of its closed neighbourhood does not increase the number of connected components. Let $Ext_Ξ±$ be the class of all connected graphs whose quotient graph obtained from modular decomposition contains no more than $Ξ±$ pairwise nonadjacent extremities. Our main contributions are as follows. First, we prove that the diameter of every $m$-edge graph in $Ext_Ξ±$ can be computed in deterministic ${\cal O}(Ξ±^3 m^{3/2})$ 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 ${\cal O}(Ξ±^2 m)$ 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 ${\cal O}(m^{2-Ξ΅})$ time for any $Ξ΅> 0$. 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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