The Generation of All Regular Rational Orthogonal Matrices
Abstract
A rational orthogonal matrix Q is an orthogonal matrix with rational entries, and Q is called regular if each of its row sum equals one, i.e., Qe = e where e is the all-one vector. This paper presents a method for generating all regular rational orthogonal matrices using the classic Cayley transformation. Specifically, we demonstrate that for any regular rational orthogonal matrix Q, there exists a permutation matrix P such that QP does not possess an eigenvalue of -1. Consequently, Q can be expressed in the form Q = (In + S)-1(In - S)P, where In is the identity matrix of order n, S is a rational skew-symmetric matrix satisfying Se = 0, and P is a permutation matrix. Central to our approach is a pivotal intermediate result, which holds independent interest: given a square matrix M, then MP has -1 as an eigenvalue for every permutation matrix P if and only if either every row sum of M is -1 or every column sum of M is -1.
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