Orthogonal and symplectic Harish-Chandra integrals and matrix product ensembles

Abstract: In this paper, we highlight the role played by orthogonal and symplectic Harish-Chandra integrals in the study of real-valued matrix product ensembles. By making use of these integrals and the matrix-valued Fourier-Laplace transform, we find the explicit eigenvalue distributions for particular Hermitian anti-symmetric matrices and particular Hermitian anti-self dual matrices, involving both sums and products. As a consequence of these results, the eigenvalue probability density function of the random product s… Show more

“…where each Y i is a particular truncation of a Haar distributed complex unitary matrix, see Proposition 4.5. This observation compliments the one in [18] made for the Gaussian case.…”

“…Also, the integrand is independent of k, while the dependence on t 12 factorises. Integrating over these variables gives We remark that the result of Corollary 4.1 includes the result of [18,Corollary 4.3], which (after a minor change of notation) tells us that with X a 2N × 2n (N ≥ n) standard real Gaussian matrix, and A = diag(a 1 , . .…”

“…In a recent work involving two of the present authors [18] it has been shown that taking a viewpoint of Hermitised products does allow for a natural theory of explicit, structured formulas for eigenvalue jPDFs and associated correlation functions for the X i being real Gaussian matrices. For this to be possible, Eq.…”

“…(1.4) must first be generalise to the form X M · · · X 2 X 1 AX T 1 X T 2 · · · X T M , (1.5) where A is a real anti-symmetric matrix. The explicit results of [18] are based on the Harish-Chandra group integral for the orthogonal group [22,12], K=O(2n) (2k)! det[cosh x i y j ] i,j=1,...,n ∆ n (x 2 )∆ n (y 2 ) , (1.6) where X, Y are 2n × 2n antisymmetric matrices with singular values {x j }, {y j }, and its analogue for the odd dimensional case.…”

“…In Section 4 the general fomalism is specialised to the case that the X i in Eq. (1.5) are either real Gaussians, so reclaiming the corresponding results in [18], or truncations of real orthogonal matrices (Jacobi ensemble). In particular the case of the jPDF of the squared singular values of A = ı1 1 n ⊗ τ 2 (τ 2 is the second Pauli matrix) surprisingly coincides with the jPDF of the…”

Multiplicative convolution of real asymmetric and real anti-symmetric matrices

“…where each Y i is a particular truncation of a Haar distributed complex unitary matrix, see Proposition 4.5. This observation compliments the one in [18] made for the Gaussian case.…”

“…Also, the integrand is independent of k, while the dependence on t 12 factorises. Integrating over these variables gives We remark that the result of Corollary 4.1 includes the result of [18,Corollary 4.3], which (after a minor change of notation) tells us that with X a 2N × 2n (N ≥ n) standard real Gaussian matrix, and A = diag(a 1 , . .…”

“…In a recent work involving two of the present authors [18] it has been shown that taking a viewpoint of Hermitised products does allow for a natural theory of explicit, structured formulas for eigenvalue jPDFs and associated correlation functions for the X i being real Gaussian matrices. For this to be possible, Eq.…”

“…(1.4) must first be generalise to the form X M · · · X 2 X 1 AX T 1 X T 2 · · · X T M , (1.5) where A is a real anti-symmetric matrix. The explicit results of [18] are based on the Harish-Chandra group integral for the orthogonal group [22,12], K=O(2n) (2k)! det[cosh x i y j ] i,j=1,...,n ∆ n (x 2 )∆ n (y 2 ) , (1.6) where X, Y are 2n × 2n antisymmetric matrices with singular values {x j }, {y j }, and its analogue for the odd dimensional case.…”

“…In Section 4 the general fomalism is specialised to the case that the X i in Eq. (1.5) are either real Gaussians, so reclaiming the corresponding results in [18], or truncations of real orthogonal matrices (Jacobi ensemble). In particular the case of the jPDF of the squared singular values of A = ı1 1 n ⊗ τ 2 (τ 2 is the second Pauli matrix) surprisingly coincides with the jPDF of the…”

Multiplicative convolution of real asymmetric and real anti-symmetric matrices

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