2010
DOI: 10.1007/978-3-642-13073-1_18
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Kernelization for Maximum Leaf Spanning Tree with Positive Vertex Weights

Abstract: Abstract. In this paper we consider a natural generalization of the well-known Max Leaf Spanning Tree problem. In the generalized Weighted Max Leaf problem we get as input an undirected connected graph G, a rational number k not smaller than 1 and a weight function w : V → Q ≥1 on the vertices, and are asked whether a spanning tree T for G exists such that the combined weight of the leaves of T is at least k. We show that it is possible to transform an instance G, w, k of Weighted Max Leaf in linear time into … Show more

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Cited by 6 publications
(4 citation statements)
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“…To avoid using weight zero, a similar result can be obtained by assigning weights m and 1 instead of 1 and 0, respectively, where m is the number of edges in G. For this case, Lemma 5.1 implies that an independent set of size t in G corresponds to a spanning arborescence of leaf weight (t + 1)m, and a similar inapproximability result holds, as Jansen [15] proved for the undirected version.…”
Section: Lemma 42 If Algorithmmentioning
confidence: 84%
See 1 more Smart Citation
“…To avoid using weight zero, a similar result can be obtained by assigning weights m and 1 instead of 1 and 0, respectively, where m is the number of edges in G. For this case, Lemma 5.1 implies that an independent set of size t in G corresponds to a spanning arborescence of leaf weight (t + 1)m, and a similar inapproximability result holds, as Jansen [15] proved for the undirected version.…”
Section: Lemma 42 If Algorithmmentioning
confidence: 84%
“…Jansen [15] proved that, unless P = NP, this version of the problem does not admit a polynomialtime ratio O(n The Independent Set problem consists of the following: given a graph G, find an independent set in G with as many vertices as possible.…”
Section: Inapproximability Of the Vertex-weighted Versionmentioning
confidence: 99%
“…Then, rETH states that there is a constant c > 0 such that there is no randomized algorithm that decides 3-SAT in time O * (2 c•n ) with (two-sided) error probability at most 1 3 (Dell et al 2014). Using the sparsification lemma (Jansen 2010) one can show the following, see Exercises 14.1 of (Cygan et al 2015a). Theorem 0.11.…”
Section: Hardnessmentioning
confidence: 99%
“…Then, rETH states that there is a constant c > 0 such that there is no randomized algorithm that decides 3-SAT in time O * (2 c•n ) with (two-sided) error probability at most 1 3 [DHM + 14]. Using the sparsification lemma [Jan10] one can show the following, see Exercises 14.1 of [CFK + 15a].…”
Section: Hardnessmentioning
confidence: 99%