The adjacency matrix of a finite graph G on n vertices is the *n x n* matrix where the non-diagonal entry *aij* is the number of edges from vertex *i* to vertex *j*, and the diagonal entry *aii*, depending on the convention, is either once or twice the number of edges (loops) from vertex *i* to itself.

Undirected graphs often use the latter convention of counting loops twice, whereas directed graphs typically use the former convention.

There exists a unique adjacency matrix for each *isomorphism* class of graphs (up to permuting rows and columns), and it is not the adjacency matrix of any other *isomorphism* class of graphs.

In the special case of a finite simple graph, the adjacency matrix is a *(0,1)-matrix* with zeros on its diagonal.

If the graph is undirected, the adjacency matrix is symmetric.

The relationship between a graph and the *eigenvalues* and *eigenvectors* of its adjacency matrix is studied in spectral graph theory.