Matrix Random Walks and the Lima Bean Law
Abstract
A matrix random walk is a stochastic process of the form Bk = (I+A1)·s(I+Ak) where Aj are independent ``step'' matrices in MN(C). With the right entry-covariance, a rescaled matrix random walk converges to Brownian motion B(t) on a matrix Lie group. In this paper, we study the eigenvalues of such rescaled matrix random walks, as N∞ and k∞. The standard Brownian motion W(t) on MN(C) has independent Gaussian entries at each t. It is bi-invariant: mutiplying on the left or right by a unitary does not change the distribution. We prove that the empirical eigenvalue distribution of any matrix random walk Bk with bi-invariant steps Aj and initial distribution converges (for fixed k as N∞) to a probability measure on C: the Brown measure of the free probability -distribution limit bk of the random walk. If the steps Aj are identically distributed with normalized Hilbert--Schmidt norm \|Aj\|2 = t, the limit law of eigenvalues is supported on a compact ``lima bean'' shaped region. We explicitly compute the limit measure and region, and characterize their phase transitions as t evolves. We prove that the Brown measure of bk converges as k∞, to the Brown measure of the free multiplicative Brownian motion, assuming only that the steps are bi-invariant and normalized in Hilbert--Schmidt norm. Thus the Brownian motion is the universal limit of rescaled matrix random walks, under very general assumptions on the distribution of steps.
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