Developing new locality results for the Prüfer code using a remarkable linear-time decoding algorithm.

Paulden, Tim; Smith, David K.

Displaying similar documents to “Developing new locality results for the Prüfer code using a remarkable linear-time decoding algorithm.”

Codings and operators in two genetic algorithms for the leaf-constrained minimum spanning tree problem

Bryant Julstrom (2004)

International Journal of Applied Mathematics and Computer Science

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The features of an evolutionary algorithm that most determine its performance are the coding by which its chromosomes represent candidate solutions to its target problem and the operators that act on that coding. Also, when a problem involves constraints, a coding that represents only valid solutions and operators that preserve that validity represent a smaller search space and result in a more effective search. Two genetic algorithms for the leaf-constrained minimum spanning tree problem...

Programming and Testing a Two-Tree Algorithm

Vassilev, Tzvetalin, Ammerlaan, Joanna (2013)

Serdica Journal of Computing

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ACM Computing Classification System (1998): G.2.2, F.2.2. Recently, Markov, Vassilev and Manev [2] proposed an algorithm for finding the longest path in 2-trees. In this paper, we describe an implementation of the algorithm. We briefly discuss the algorithm and present example that helps the reader grasp the main algorithmic ideas. Further, we discuss the important stages in the implementation of the algorithm and justify the decisions taken. Then, we present experimental...

A Bicriterion Steiner Tree Problem on Graph

Mirko Vujošević, Milan Stanojević (2003)

The Yugoslav Journal of Operations Research

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A few remarks on the history of MST-problem

Jaroslav Nešetřil (1997)

Archivum Mathematicum

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On the background of Borůvka’s pioneering work we present a survey of the development related to the Minimum Spanning Tree Problem. We also complement the historical paper Graham-Hell [GH] by a few remarks and provide an update of the extensive literature devoted to this problem.

Algorithm 42. Enclosure of a point to the minimum spanning tree

G. Trybuś (1976)

Applicationes Mathematicae

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Clustering in trees: Optimizing cluster sizes and number of subtrees.

Hambrusch, Susanne E., Liu, Chuan-Ming, Lim, Hyeong-Seok (2000)

Journal of Graph Algorithms and Applications

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The color-balanced spanning tree problem

Štefan Berežný, Vladimír Lacko (2005)

Kybernetika

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Suppose a graph $G = (V, E)$ whose edges are partitioned into $p$ disjoint categories (colors) is given. In the color-balanced spanning tree problem a spanning tree is looked for that minimizes the variability in the number of edges from different categories. We show that polynomiality of this problem depends on the number $p$ of categories and present some polynomial algorithm.

The triangles method to build $X$ -trees from incomplete distance matrices

Alain Guénoche, Bruno Leclerc (2001)

RAIRO - Operations Research - Recherche Opérationnelle

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A method to infer $X$ -trees (valued trees having $X$ as set of leaves) from incomplete distance arrays (where some entries are uncertain or unknown) is described. It allows us to build an unrooted tree using only 2 $n$ -3 distance values between the $n$ elements of $X$ , if they fulfill some explicit conditions. This construction is based on the mapping between $X$ -tree and a weighted generalized 2-tree spanning $X$ .

Three new heuristics for the Steiner problem in graphs.

Diané, M., Plesník, Ján (1991)

Acta Mathematica Universitatis Comenianae. New Series

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Efficient drawing of RNA secondary structure.

Auber, David, Delest, Maylis, Domenger, Jean-Philippe, Dulucq, Serge (2006)

Journal of Graph Algorithms and Applications

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