On the real zeros of random trigonometric polynomials with dependent coefficients
arXiv:1706.01654
Abstract
We consider random trigonometric polynomials of the form \[ f_n(t):=\sum_{1\le k \le n} a_{k} \cos(kt) + b_{k} \sin(kt), \] whose entries $(a_{k})_{k\ge 1}$ and $(b_{k})_{k\ge 1}$ are given by two independent stationary Gaussian processes with the same correlation function $Ï$. Under mild assumptions on the spectral function $Ï_Ï$ associated with $Ï$, we prove that the expectation of the number $N_n([0,2Ï])$ of real roots of $f_n$ in the interval $[0,2Ï]$ satisfies \[ \lim_{n \to +\infty} \frac{\mathbb E\left [N_n([0,2Ï])\right]}{n} = \frac{2}{\sqrt{3}}. \] The latter result not only covers the well-known situation of independent coefficients but allow us to deal with long range correlations. In particular it englobes the case where the random coefficients are given by a fractional Brownian noise with any Hurst parameter.