English

Enumerating the Classes of Local Equivalency in Graphs

Combinatorics 2007-07-05 v2

Abstract

There are local operators on (labeled) graphs GG with labels (gij)(g_{ij}) coming from a finite field. If the filed is binary, in other words, if the graph is ordinary, the operation is just the local complementation. That is, to choose a vertex and complement the subgraph induced by its neighbors. But, in the general case, there are two different types of operators. The first type is the following. Let vv be a vertex of the graph and aFqa\in \mathbf{F}_q, the finite field of qq elements. The operator is to obtain a graph with labels gij=gij+agvigvjg'_{ij}=g_{ij}+ag_{vi}g_{vj}. For the second type of operators, let 0bFq0\neq b\in \mathbf{F}_q and the resulted graph is a graph with labels gvi=bgvig''_{vi}=bg_{vi} and gij=gijg''_{ij}=g_{ij}, for i,ji,j unequal to vv. The local complementation operator (binary case) has appeared in combinatorial theory, and its properties have studied in the literature. Recently, a profound relation between local operators on graphs and quantum stabilizer codes has been found, and it has become a natural question to recognize equivalency classes under these operators. In the present article, we show that the number of graphs locally equivalent to a given graph is at most q2n+1q^{2n+1}, and consequently, the number of classes of local equivalency is qn22o(n)q^{\frac{n^2}{2}-o(n)}.

Keywords

Cite

@article{arxiv.math/0702267,
  title  = {Enumerating the Classes of Local Equivalency in Graphs},
  author = {Mohsen Bahramgiri and Salman Beigi},
  journal= {arXiv preprint arXiv:math/0702267},
  year   = {2007}
}

Comments

22 pages, no figure, more clear presentation and minor errors fixed