Hill's Spectral Curves and the Invariant Measure of the Periodic KdV Equation

Abstract

This paper analyses the periodic spectrum of Schr\"odinger's equation -f''+qf=λ f when the potential is real, periodic, random and subject to the invariant measure Nβ of the periodic KdV equation. This Nβ is the modified canonical ensemble, as given by Bourgain (Comm. Math. Phys. 166 (1994), 1--26), and Nβ satisfies a logarithmic Sobolev inequality. Associated concentration inequalities control the fluctuations of the periodic eigenvalues (λn). For β, N>0 small, there exists a set of positive Nβ measure such that ( 2(λ2n+λ2n-1))n=0∞ gives a sampling sequence for Paley--Wiener space PW(π ) and the reproducing kernels give a Riesz basis. Let (μj)j=1∞ be the tied spectrum; then (2μj-j) belongs to a Hilbert cube in 2 and is distributed according to a measure that satisfies Gaussian concentration for Lipschitz functions. The sampling sequence (μj)j=1∞ arises from a divisor on the spectral curve, which is hyperelliptic of infinite genus. The linear statistics Σj g(λ2j) with test function g∈ PW(π) satisfy Gaussian concentration inequalities.