Products of random matrices from polynomial ensembles

Kieburg, Mario; Kösters, Holger

doi:10.1214/17-aihp877

Cited by 37 publications

(95 citation statements)

References 87 publications

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“…This is no longer true for the real case; see [31] for an extended discussion of the role of group integrals in the computation of the jPDF of the singular values for product matrices of Gaussians or truncated unitaries. Another, closely related, viewpoint has emerged from the recent joint work of Kösters with one of the authors [29,30] which is based on harmonic analysis [23]. Here, generalising the role played by the Mellin transform in the study or products of scalar random variables, a theory of random product matrices based on the spherical transform has been proposed.…”

Section: Introductionmentioning

confidence: 99%

“…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. With regard to the harmonic analysis approach [29,30], the natural question of an understanding of explicit formulas in relation to the Hermitised product (1.5) from the viewpoint of spherical transforms arises. The purpose of the present work is to provide such an insight in the case that the matrices are all even dimensional.…”

Section: Introductionmentioning

confidence: 99%

“…(1.5). For this purpose we introduce our notations and review the main ideas of the harmonic analysis approach of [29,30]. Theorem 2.3 specifies in terms of determinants and Vandermonde products the central object of this study, namely the corresponding spherical function Φ(s; x).…”

Section: Introductionmentioning

confidence: 99%

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Multiplicative convolution of real asymmetric and real anti-symmetric matrices

Kieburg

Forrester

Ipsen

2019

Advances in Pure and Applied Mathematics

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AbstractThe singular values of products of standard complex Gaussian random matrices, or sub-blocks of Haar distributed unitary matrices, have the property that their probability distribution has an explicit, structured form referred to as a polynomial ensemble. It is furthermore the case that the corresponding bi-orthogonal system can be determined in terms of Meijer G-functions, and the correlation kernel given as an explicit double contour integral. It has recently been shown that the Hermitised product {X_{M}\cdots X_{2}X_{1}AX_{1}^{T}X_{2}^{T}\cdots X_{M}^{T}}, where each {X_{i}} is a standard real Gaussian matrix and A is real anti-symmetric, exhibits analogous properties. Here we use the theory of spherical functions and transforms to present a theory which, for even dimensions, includes these properties of the latter product as a special case. As an example we show that the theory also allows for a treatment of this class of Hermitised product when the {X_{i}} are chosen as sub-blocks of Haar distributed real orthogonal matrices.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Multiplicative convolution of real asymmetric and real anti-symmetric matrices

Kieburg

Forrester

Ipsen

2019

Advances in Pure and Applied Mathematics

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“…In several works, e.g. [10,[40][41][42][43], it has been shown for various kinds of X j being i.i.d. that the distributions of the Lyapunov exponents λ j become asymptotically Gaussian when choosing M N .…”

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confidence: 99%

From integrable to chaotic systems: Universal local statistics of Lyapunov exponents

Akemann¹,

Burda²,

Kieburg³

2019

EPL

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Systems where time evolution follows a multiplicative process are ubiquitous in physics. We study a toy model for such systems where each time step is given by multiplication with an independent random N ×N matrix with complex Gaussian elements, the complex Ginibre ensemble. This model allows to explicitly compute the Lyapunov exponents and local correlations amongst them, when the number of factors M becomes large. While the smallest eigenvalues always remain deterministic, which is also the case for many chaotic quantum systems, we identify a critical double scaling limit N ∼ M for the rest of the spectrum. It interpolates between the known deterministic behaviour of the Lyapunov exponents for M N (or N fixed) and universal random matrix statistics for M N (or M fixed), characterising chaotic behaviour. After unfolding this agrees with Dyson's Brownian Motion starting from equidistant positions in the bulk and at the soft edge of the spectrum. This universality statement is further corroborated by numerical experiments, multiplying different kinds of random matrices. It leads us to conjecture a much wider applicability in complex systems, that display a transition from deterministic to chaotic behaviour.

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“…It is known that multiplication of (real/complex/quaternion at β = 1, 2, 4) matrices is intimately linked to multiplication of corresponding Jack (=zonal) polynomials, which become Schur polynomials in the case of the complex field (β = 2) that we discuss here. This is discussed by Macdonald [34, Chapter VII], Forrester [20,Section 13.4.3], and more recently used, e.g., by Kieburg, Kosters [29] and by Gorin, Marcus [24]. If we consider a version of the multidimensional Fourier transform for the Schur measures (the appropriate version was introduced by Gorin, Panova [23], Bufetov, Gorin [16] under the name Schur generating functions), then being a Schur measure or its continuous limit is equivalent to the factorization of this transform into a product of one variable functions.…”

Section: Introductionmentioning

confidence: 99%

Product Matrix Processes as Limits of Random Plane Partitions

Borodin

Gorin

Strahov

2019

International Mathematics Research Notices

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We consider a random process with discrete time formed by singular values of products of truncations of Haar distributed unitary matrices. We show that this process can be understood as a scaling limit of the Schur process, which gives determinantal formulas for (dynamical) correlation functions and a contour integral representation for the correlation kernel. The relation with the Schur processes implies that the continuous limit of marginals for q-distributed plane partitions coincides with the joint law of singular values for products of truncations of Haar-distributed random unitary matrices. We provide structural reasons for this coincidence that may also extend to other classes of random matrices.

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Products of random matrices from polynomial ensembles

Cited by 37 publications

References 87 publications

Multiplicative convolution of real asymmetric and real anti-symmetric matrices

Multiplicative convolution of real asymmetric and real anti-symmetric matrices

From integrable to chaotic systems: Universal local statistics of Lyapunov exponents

Product Matrix Processes as Limits of Random Plane Partitions

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