On symmetric association schemes and associated quotient-polynomial graphs

Abstract

Let denote an undirected, connected, regular graph with vertex set X, adjacency matrix A, and d+1 distinct eigenvalues. Let A= A() denote the subalgebra of MatX( C) generated by A. We refer to A as the adjacency algebra of . In this paper we investigate algebraic and combinatorial structure of for which the adjacency algebra A is closed under Hadamard multiplication. In particular, under this simple assumption, we show the following: (i) A has a standard basis \I,F1,…,Fd\; (ii) for every vertex there exists identical distance-faithful intersection diagram of with d+1 cells; (iii) the graph is quotient-polynomial; and (iv) if we pick F∈ \I,F1,…,Fd\ then F has d+1 distinct eigenvalues if and only if span\I,F1,…,Fd\=span\I,F,…,Fd\. We describe the combinatorial structure of quotient-polynomial graphs with diameter 2 and 4 distinct eigenvalues. As a consequence of the technique from the paper we give an algorithm which computes the number of distinct eigenvalues of any Hermitian matrix using only elementary operations. When such a matrix is the adjacency matrix of a graph , a simple variation of the algorithm allow us to decide wheter is distance-regular or not. In this context, we also propose an algorithm to find which distance-i matrices are polynomial in A, giving also these polynomials.