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K-tree

In today's world, K-tree is a highly relevant topic that has captured the attention of people of all ages, genders and cultures. With the advancement of technology and access to information, K-tree has become a central point of discussion and interest in modern society. Whether through social networks, media or daily conversations, K-tree has managed to impact the way we think and act in our daily lives. This is why it is crucial to delve deeper into this topic to understand its importance and implications at both an individual and collective level.

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The Goldner–Harary graph, an example of a planar 3-tree.

In graph theory, a k-tree is an undirected graph formed by starting with a (k + 1)-vertex complete graph and then repeatedly adding vertices in such a way that each added vertex v has exactly k neighbors U such that, together, the k + 1 vertices formed by v and U form a clique.[1][2]

Characterizations

The k-trees are exactly the maximal graphs with a treewidth of k ("maximal" means that no more edges can be added without increasing their treewidth).[2] They are also exactly the chordal graphs all of whose maximal cliques are the same size k + 1 and all of whose minimal clique separators are also all the same size k.[1]

1-trees are the same as trees. 2-trees are maximal series–parallel graphs,[3] and include also the maximal outerplanar graphs. Planar 3-trees are also known as Apollonian networks.[4]

The graphs that have treewidth at most k are exactly the subgraphs of k-trees, and for this reason they are called partial k-trees.[2]

The graphs formed by the edges and vertices of k-dimensional stacked polytopes, polytopes formed by starting from a simplex and then repeatedly gluing simplices onto the faces of the polytope, are k-trees when k ≥ 3.[5] This gluing process mimics the construction of k-trees by adding vertices to a clique.[6] A k-tree is the graph of a stacked polytope if and only if no three (k + 1)-vertex cliques have k vertices in common.[7]

References

  1. ^ a b Patil, H. P. (1986), "On the structure of k-trees", Journal of Combinatorics, Information and System Sciences, 11 (2–4): 57–64, MR 0966069.
  2. ^ a b c Nešetřil, Jaroslav; Ossona de Mendez, Patrice (2008), "Structural Properties of Sparse Graphs" (PDF), in Grötschel, Martin; Katona, Gyula O. H. (eds.), Building Bridges: between Mathematics and Computer Science, Bolyai Society Mathematical Studies, vol. 19, Springer-Verlag, p. 390, ISBN 978-3-540-85218-6.
  3. ^ Hwang, Frank; Richards, Dana; Winter, Pawel (1992), The Steiner Tree Problem, Annals of Discrete Mathematics (North-Holland Mathematics Studies), vol. 53, Elsevier, p. 177, ISBN 978-0-444-89098-6.
  4. ^ Distances in random Apollonian network structures Archived 2011-07-21 at the Wayback Machine, talk slides by Olivier Bodini, Alexis Darrasse, and Michèle Soria from a talk at FPSAC 2008, accessed 2011-03-06.
  5. ^ Koch, Etan; Perles, Micha A. (1976), "Covering efficiency of trees and k-trees", Proceedings of the Seventh Southeastern Conference on Combinatorics, Graph Theory, and Computing (Louisiana State Univ., Baton Rouge, La., 1976), Utilitas Math., Winnipeg, Man., pp. 391–420. Congressus Numerantium, No. XVII, MR 0457265. See in particular p. 420.
  6. ^ Below, Alexander; De Loera, Jesús A.; Richter-Gebert, Jürgen (February 2004), "The complexity of finding small triangulations of convex 3-polytopes", Journal of Algorithms, 50 (2): 134–167, arXiv:math/0012177, doi:10.1016/s0196-6774(03)00092-0
  7. ^ Kleinschmidt, Peter (1 December 1976), "Eine graphentheoretische Kennzeichnung der Stapelpolytope", Archiv der Mathematik, 27 (1): 663–667, doi:10.1007/BF01224736
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