Zero correlations and averaged fields of orthonormal Gaussian functions

Abstract

We consider the family of point processes \Zfn\n=0∞ of zeros of Gaussian random functions \fn(z,z)\n=0∞ , arising from the Gaussian Entire Function \[ f0(z):=Σk=0∞ ζk zkk!, ζk NC(0,1) i.i.d. \] by iteration of the Landau raising operator, and orthonormal at each point in expectation in the sense that \[ E[ e- z2fn(z,z)fn (z,z)] =δnn'. \] We first show that the normalized pair correlations gn,n+k(z,w) of the pairs (Zfn,Zfn+k) exhibit a pattern reminiscent of the classical interlacing of zeros of orthogonal polynomials: when w→ z, gn,n+k displays repulsion for k=1, attraction for k=2, and no short-range second-order correlation for k 3. We complement this with the convergence of real-valued averaged fields on compacts K ⊂ C, \[ N ∞ 1NΣn=0N-1 fn(z,z)e- z22 2 → 1 almost surely in C(K), \] and a functional central limit theorem for the corresponding scaled fluctuations, which converge to the Gaussian process \[G(z) = 1π ∫C 1B(z,1)(u) dWR(u), \] where WR denotes real white noise on C and B(z,1) is the unit disk centered at z. The results are motivated by problems in signal processing. Due to an identification with white noise spectrograms, they confirm conjectures of Flandrin and Bayram-Baraniuk and provide a rationale for the efficiency of high resolution time-frequency algorithms, namely ConceFT, by Daubechies, Wang and Wu.