Vertex identification to a forest

arXiv - MATH - Combinatorics Pub Date : 2024-09-13 DOI:arxiv-2409.08883

Laure Morelle, Ignasi Sau, Dimitrios M. Thilikos

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Abstract

Let $\mathcal{H}$ be a graph class and $k\in\mathbb{N}$. We say a graph $G$ admits a \emph{$k$-identification to $\mathcal{H}$} if there is a partition $\mathcal{P}$ of some set $X\subseteq V(G)$ of size at most $k$ such that after identifying each part in $\mathcal{P}$ to a single vertex, the resulting graph belongs to $\mathcal{H}$. The graph parameter ${\sf id}_{\mathcal{H}}$ is defined so that ${\sf id}_{\mathcal{H}}(G)$ is the minimum $k$ such that $G$ admits a $k$-identification to $\mathcal{H}$, and the problem of \textsc{Identification to $\mathcal{H}$} asks, given a graph $G$ and $k\in\mathbb{N}$, whether ${\sf id}_{\mathcal{H}}(G)\le k$. If we set $\mathcal{H}$ to be the class $\mathcal{F}$ of acyclic graphs, we generate the problem \textsc{Identification to Forest}, which we show to be {\sf NP}-complete. We prove that, when parameterized by the size $k$ of the identification set, it admits a kernel of size $2k+1$. For our kernel we reveal a close relation of \textsc{Identification to Forest} with the \textsc{Vertex Cover} problem. We also study the combinatorics of the \textsf{yes}-instances of \textsc{Identification to $\mathcal{H}$}, i.e., the class $\mathcal{H}^{(k)}:=\{G\mid {\sf id}_{\mathcal{H}}(G)\le k\}$, {which we show to be minor-closed for every $k$} when $\mathcal{H}$ is minor-closed. We prove that the minor-obstructions of $\mathcal{F}^{(k)}$ are of size at most $2k+4$. We also prove that every graph $G$ such that ${\sf id}_{\mathcal{F}}(G)$ is sufficiently big contains as a minor either a cycle on $k$ vertices, or $k$ disjoint triangles, or the \emph{$k$-marguerite} graph, that is the graph obtained by $k$ disjoint triangles by identifying one vertex of each of them into the same vertex.

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森林顶点识别

假设 $mathcal{H}$ 是一个图类，且 $k\in\mathbb{N}$ 是一个图。如果在某个大小至多为 $k$ 的集合 $Xsubseteq V(G)$ 中存在一个分区${emph{$k$-identification}${emathcal{H}$}$，使得将 ${emathcal{P}$中的每个部分识别为一个顶点后，得到的图属于 $\mathcal{H}$，那么我们就说这个图 $G$允许对 $\mathcal{H}$进行\emph{$k$-identification。图参数 ${sf id}_{mathcal{H}}$ 的定义是这样的：${\sf id}_{mathcal{H}}(G)$ 是最小的 $k$，使得 $G$ 允许 $k$ 识别 $\mathcal{H}$ 、而textsc{指向 $\mathcal{H}$ 的问题是，给定一个图 $G$ 和$k\in\mathbb{N}$，问 ${sf id}_{mathcal{H}}(G)\le k$ 是否指向 $\sf id}_{mathcal{H}}(G)\le k$ 。如果我们把$\mathcal{H}$设为无循环图的类$\mathcal{F}$，我们就会产生问题 \textsc{Identification to Forest}，我们证明这个问题是{\sfNP}完备的。我们证明，当以识别集的大小 $k$ 为参数时，它允许一个大小为 2k+1$ 的内核。对于我们的内核，我们揭示了 \textsc{Identification to Forest} 与 \textsc{VertexCover} 问题的密切关系。我们还研究了textsf{yes}-instances of \textsc{Identification to $\mathcal{H}$}的组合学，即类$\mathcal{H}^{(k)}:=\{G\mid {\sf id}_{mathcal{H}}(G)\le k\}$, {当$\mathcal{H}$是次要封闭的时候，我们证明它对每一个$k$$都是次要封闭的。我们证明，$\mathcal{F}^{(k)}$ 的次要结构的大小最多为 2k+4$。我们还证明了每个图 $G$，使得 ${\sf id}_{\mathcal{F}}(G)$ 发得足够大，都包含一个次要图，要么是 $k$ 顶点上的循环，要么是 $k$ 不相邻的三角形，要么是 \emph{$k$-marguerite} 图，即由 $k$ 不相邻的三角形通过将其中每个三角形的一个顶点识别为同一个顶点而得到的图。

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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arXiv - MATH - Combinatorics

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