| Turán graph | |||||||||||||||||
| Vertices: | n | ||||||||||||||||
| Edges: | ~ \left(1-
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| Radius: | \left\{\begin{array}{ll}infty&r=1\ 2&r\len/2\ 1&otherwise\end{array}\right. \left\{\begin{array}{ll}infty&r=1\ 1&r=n\ 2&otherwise\end{array}\right. \left\{\begin{array}{ll}infty&r=1\vee(n\le3\wedger\le2)\ 4&r=2\ 3&otherwise\end{array}\right. r T(n,r) T(n,r) n r q s n r n=qr+s Kq+1, \left(1-
+{s\choose2} For r\le7
s q+1 r-s q n-q-1 n-q n r s=0 Turán's theoremSee main article: Turán's theorem. Turán graphs are named after Pál Turán, who used them to prove Turán's theorem, an important result in extremal graph theory. By the pigeonhole principle, every set of r + 1 vertices in the Turán graph includes two vertices in the same partition subset; therefore, the Turán graph does not contain a clique of size r + 1. According to Turán's theorem, the Turán graph has the maximum possible number of edges among all (r + 1)-clique-free graphs with n vertices. show that the Turán graph is also the only (r + 1)-clique-free graph of order n in which every subset of αn vertices spans at least
-1)n2 Special casesSeveral choices of the parameter r in a Turán graph lead to notable graphs that have been independently studied. The Turán graph T(2n,n) can be formed by removing a perfect matching from a complete graph K2n. As showed, this graph has boxicity exactly n; it is sometimes known as the Roberts graph. This graph is also the 1-skeleton of an n-dimensional cross-polytope; for instance, the graph T(6,3) = K2,2,2 is the octahedral graph, the graph of the regular octahedron. If n couples go to a party, and each person shakes hands with every person except his or her partner, then this graph describes the set of handshakes that take place; for this reason, it is also called the cocktail party graph. The Turán graph T(n,2) is a complete bipartite graph and, when n is even, a Moore graph. When r is a divisor of n, the Turán graph is symmetric and strongly regular, although some authors consider Turán graphs to be a trivial case of strong regularity and therefore exclude them from the definition of a strongly regular graph. The class of Turán graphs can have exponentially many maximal cliques, meaning this class does not have few cliques. For example, the Turán graph T(n,\lceiln/3\rceil) Other propertiesEvery Turán graph is a cograph; that is, it can be formed from individual vertices by a sequence of disjoint union and complement operations. Specifically, such a sequence can begin by forming each of the independent sets of the Turán graph as a disjoint union of isolated vertices. Then, the overall graph is the complement of the disjoint union of the complements of these independent sets. show that the Turán graphs are chromatically unique: no other graphs have the same chromatic polynomials. Nikiforov (2005) uses Turán graphs to supply a lower bound for the sum of the kth eigenvalues of a graph and its complement. develop an efficient algorithm for finding clusters of orthologous groups of genes in genome data, by representing the data as a graph and searching for large Turán subgraphs. Turán graphs also have some interesting properties related to geometric graph theory. give a lower bound of Ω((rn)3/4) on the volume of any three-dimensional grid embedding of the Turán graph. conjectures that the maximum sum of squared distances, among n points with unit diameter in Rd, is attained for a configuration formed by embedding a Turán graph onto the vertices of a regular simplex. An n-vertex graph G is a subgraph of a Turán graph T(n,r) if and only if G admits an equitable coloring with r colors. The partition of the Turán graph into independent sets corresponds to the partition of G into color classes. In particular, the Turán graph is the unique maximal n-vertex graph with an r-color equitable coloring. References
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