Graph eigenvectors, fundamental weights and centrality metrics for nodes in networks

Abstract

Several expressions for the j-th component ( xk)j of the k-th eigenvector xk of a symmetric matrix A belonging to eigenvalue λk and normalized as xkTxk=1 are presented. In particular, the expression \[ ( xk)j2=-1cA( λk) ( A\ j\ -λkI) \] where cA( λ) =( A-λ I) is the characteristic polynomial of A, cA( λ) =dcA( λ) dλ and A\ j\ is obtained from A by removal of row j and column j, suggests us to consider the square eigenvector component as a graph centrality metric for node j that reflects the impact of the removal of node j from the graph at an eigenfrequency/eigenvalue λk of a graph related matrix (such as the adjacency or Laplacian matrix). Removal of nodes in a graph relates to the robustness of a graph. The set of such nodal centrality metrics, the squared eigenvector components ( xk)j2 of the adjacency matrix over all eigenvalue λk for each node j, is 'ideal' in the sense of being complete, almost uncorrelated and mathematically precisely defined and computable. Fundamental weights (column sum of X) and dual fundamental weights (row sum of X) are introduced as spectral metrics that condense information embedded in the orthogonal eigenvector matrix X, with elements Xij=( xj)i. In addition to the criterion If the algebraic connectivity is positive, then the graph is connected, we found an alternative condition: If 1≤ k≤ N( λk2(A)) =d, then the graph is disconnected.