On *-Convergence of Schur-Hadamard Products of Independent Nonsymmetric Random Matrices

Abstract

Let \xα\α ∈ Z and \yα\α ∈ Z be two independent collections of zero mean, unit variance random variables with uniformly bounded moments of all orders. Consider a nonsymmetric Toeplitz matrix Xn = ((xi - j))1 i, j n and a Hankel matrix Yn = ((yi + j))1 i, j n, and let Mn = Xn Yn be their elementwise/Schur-Hadamard product. In this article, we show that almost surely, n-1/2Mn, as an element of the *-probability space (Mn(C), 1ntr), converges in *-distribution to a circular variable. With i.i.d. Rademacher entries, this construction gives a matrix model for circular variables with only O(n) bits of randomness. We also consider a dependent setup where \xα\ and \yβ\ are independent strongly multiplicative systems (\`a la Gaposhkin [7]) satisfying an additional admissibility condition, and have uniformly bounded moments of all orders -- a nontrivial example of such a system being \2(2n π U)\n ∈ Z+, where U Uniform(0, 1). In this case, we show in-expectation and in-probability convergence of the *-moments of n-1/2Mn to those of a circular variable. Finally, we generalise our results to Schur-Hadamard products of structured random matrices of the form Xn = ((xLX(i, j)))1 i, j n and Yn = ((yLY(i, j)))1 i, j n, under certain assumptions on the link-functions LX and LY, most notably the injectivity of the map (i, j) (LX(i, j), LY(i, j)). Based on numerical evidence, we conjecture that the circular law μcirc, i.e. the uniform measure on the unit disk of C, which is also the Brown measure of a circular variable, is in fact the limiting spectral measure of n-1/2Mn.