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引用次数: 0
摘要
在连通的简单图 G = (V,E)中,V 的每个顶点都由颜色集合 C={c_1, c_2,..., c_{\alpha}} 中的一种颜色着色。我们取 V 的一个子集 S,这样对于 V\S 中的每个顶点 v,至少有一个相同颜色的顶点出现在它在 S 中的近邻集合中。 我们把这样的 S 称为一致子集(CS)。最小一致子集(MCS)问题是计算一个最小大小的一致子集。对于一般图(包括平面图)来说,MCS 是一个 NP-完全问题。我们将研究扩展到区间图和圆图,试图全面了解不同图类中 MCS 问题的计算复杂性。严格一致子集是一致子集问题的一个变种。我们取 V 的一个子集 S^{prime},对于 VS^{prime} 中的每个顶点 v,S 中其最近邻集合中的所有顶点都与 v 具有相同的颜色,我们把这样的 S^{prime} 称为严格一致子集(SCS)。最小严格一致子集(MSCS)问题就是计算一个最小大小的一致子集。我们证明,在一般图中,MSCS 是 NP 难问题。我们展示了树中的 2 近似值。随后,我们展示了树中的多项式时间算法。随后,我们展示了路径、蜘蛛和梳状图中更快的多项式时间算法。
Minimum Strict Consistent Subset in Paths, Spiders, Combs and Trees
In a connected simple graph G = (V,E), each vertex of V is colored by a color
from the set of colors C={c_1, c_2,..., c_{\alpha}}. We take a subset S of V,
such that for every vertex v in V\S, at least one vertex of the same color is
present in its set of nearest neighbors in S. We refer to such a S as a
consistent subset (CS) The Minimum Consistent Subset (MCS) problem is the
computation of a consistent subset of the minimum size. It is established that
MCS is NP-complete for general graphs, including planar graphs. We expand our
study to interval graphs and circle graphs in an attempt to gain a complete
understanding of the computational complexity of the MCS problem across various
graph classes. The strict consistent subset is a variant of consistent subset
problems. We take a subset S^{\prime} of V, such that for every vertex v in
V\S^{\prime}, all the vertices in its set of nearest neighbors in S have the
same color as v. We refer to such a S^{\prime} as a strict consistent subset
(SCS). The Minimum Strict Consistent Subset (MSCS) problem is the computation
of a consistent subset of the minimum size. We demonstrate that MSCS is NP-hard in general graphs. We show a
2-approximation in trees. Later, we show polynomial-time algorithms in trees.
Later, we demonstrate faster polynomial-time algorithms in paths, spiders, and
combs.