On the number of real eigenvalues of a product of truncated orthogonal random matrices

Abstract

Let O be chosen uniformly at random from the group of (N+L) × (N+L) orthogonal matrices. Denote by O the upper-left N × N corner of O, which we refer to as a truncation of O. In this paper we prove two conjectures of Forrester, Ipsen and Kumar (2020) on the number of real eigenvalues N(m)R of the product matrix O1… Om, where the matrices \Oj\j=1m are independent copies of O. When L grows in proportion to N, we prove that E(N(m)R) = 2m Lπ\,arctanh(NN+L) + O(1), N ∞. We also prove the conjectured form of the limiting real eigenvalue distribution of the product matrix. Finally, we consider the opposite regime where L is fixed with respect to N, known as the regime of weak non-orthogonality. In this case each matrix in the product is very close to an orthogonal matrix. We show that E(N(m)R) cL,m\,(N) as N ∞ and compute the constant cL,m explicitly. These results generalise the known results in the one matrix case due to Khoruzhenko, Sommers and \.Zyczkowski (2010).