A Quantitative Central Limit Theorem for the Euler-Poincar\'e Characteristic of Random Spherical Eigenfunctions

TL;DR

This paper proves a quantitative Central Limit Theorem for the Euler-Poincaré characteristic of excursion sets of random spherical eigenfunctions, revealing its asymptotic behavior and dependence on the threshold level.

Contribution

It introduces a new quantitative CLT for the Euler-Poincaré characteristic in the spherical setting, with a detailed Wiener-chaos decomposition and threshold dependence analysis.

Findings

Asymptotic convergence to a Gaussian distribution in Wasserstein distance.

Dominance of the second-order Wiener-chaos component.

Degenerate dependence on the threshold level u.

Abstract

We establish here a Quantitative Central Limit Theorem (in Wasserstein distance) for the Euler-Poincar\'{e} Characteristic of excursion sets of random spherical eigenfunctions in dimension 2. Our proof is based upon a decomposition of the Euler-Poincar\'{e} Characteristic into different Wiener-chaos components: we prove that its asymptotic behaviour is dominated by a single term, corresponding to the chaotic component of order two. As a consequence, we show how the asymptotic dependence on the threshold level $u$ is fully degenerate, i.e., the Euler-Poincar\'{e} Characteristic converges to a single random variable times a deterministic function of the threshold. This deterministic function has a zero at the origin, where the variance is thus asymptotically of smaller order. Our results can be written as an asymptotic second-order Gaussian Kinematic Formula for the excursion sets of Gaussian spherical harmonics.