Tridiagonal Models for Dyson Brownian Motion

Abstract

In this paper, we consider tridiagonal matrices the eigenvalues of which evolve according to β-Dyson Brownian motion. This is the stochastic gradient flow on Rn given by, for all 1 ≤ i ≤ n, \[ dλi,t = 2βdZi,t - ( V'(λi)2 - Σj: j ≠ i 1λi - λj )\,dt \] where V is a constraining potential and \ Zi,t \1n are independent standard Brownian motions. This flow is stationary with respect to the distribution \[ βN(λ) = 1ZβN e-β2 ( -Σ1 ≤ i ≠ j ≤ N |λi - λj| + Σi=1N V(λi) ) . \] The particular choice of V(t)=2t2 leads to an eigenvalue distribution constrained to lie roughly in (-n,n). We study evolution of the entries of one choice of tridiagonal flow for this V in the n ∞ limit. On the way to describing the evolution of the tridiagonal matrices we give the derivative of the Lanczos tridiagonalization algorithm under perturbation.