Kautz graph

Example of Kautz graph on 3 characters with string length 2 (on the left) and 3 (on the right); the edges on the left correspond to the vertices on the right.

The Kautz graph K_M^{N + 1} is a directed graph of degree M and dimension N+
1, which has (M +1)M^{N} vertices labeled by all possible strings s_0 \cdots s_N of length N +
1 which are composed of characters s_i chosen from an alphabet A containing M + 1 distinct symbols, subject to the condition that adjacent characters in the string cannot be equal (s_i \neq s_{i+ 1}).

The Kautz graph K_M^{N + 1} has (M + 1)M^{N
+ 1} edges

\{(s_0 s_1 \cdots s_N,s_1 s_2 \cdots s_N s_{N + 1})| \; s_i \in A \; s_i \neq s_{i  + 1} \} \,

It is natural to label each such edge of K_M^{N + 1} as s_0s_1 \cdots s_{N + 1}, giving a one-to-one correspondence between edges of the Kautz graph K_M^{N + 1} and vertices of the Kautz graph K_M^{N + 2}.

Kautz graphs are closely related to De Bruijn graphs.

Properties

In computing

The Kautz graph has been used as a network topology for connecting processors in high-performance computing[1] and fault-tolerant computing[2] applications: such a network is known as a Kautz network.

Notes

  1. Darcy, Jeff (2007-12-31). "The Kautz Graph". Canned Platypus. External link in |publisher= (help)
  2. Li, Dongsheng; Xicheng Lu; Jinshu Su (2004). "Graph-Theoretic Analysis of Kautz Topology and DHT Schemes". Network and Parallel Computing: IFIP International Conference. Wuhan, China: NPC. pp. 308–315. ISBN 3-540-23388-1. Retrieved 2008-03-05.

This article incorporates material from Kautz graph on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.

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