English

Large Deviation Principles for Lacunary Sums

Probability 2020-12-11 v1 Dynamical Systems Number Theory

Abstract

Let (ak)kN(a_k)_{k\in\mathbb N} be a sequence of integers satisfying the Hadamard gap condition ak+1/ak>q>1a_{k+1}/a_k>q>1 for all kNk\in\mathbb N, and let Sn(ω)=k=1ncos(2πakω),nN,  ω[0,1]. S_n(\omega) = \sum_{k=1}^n\cos(2\pi a_k \omega),\qquad n\in\mathbb N,\;\omega\in [0,1]. The lacunary trigonometric sum SnS_n is known to exhibit several properties typical for sums of independent random variables. In this paper we initiate the investigation of large deviation principles (LDPs) for SnS_n. Under the large gap condition ak+1/aka_{k+1}/a_k\to\infty, we prove that (Sn/n)nN(S_n/n)_{n\in\mathbb N} satisfies an LDP with speed nn and the same rate function I~\tilde{I} as for sums of independent random variables with the arcsine distribution, but show that the LDP may fail to hold when we only assume the Hadamard gap condition. However, we prove that in the special case ak=qka_k=q^k for some q{2,3,}q\in \{2,3,\ldots\}, (Sn/n)nN(S_n/n)_{n\in\mathbb N} satisfies an LDP with speed nn and a rate function IqI_q different from I~\tilde{I}. We also show that IqI_q converges pointwise to I~\tilde I as qq\to\infty and construct a random perturbation (ak)kN(a_k)_{k\in\mathbb N} of the sequence (2k)kN(2^k)_{k\in\mathbb N} for which ak+1/ak2a_{k+1}/a_k\to 2 as kk\to\infty, but for which (Sn/n)nN(S_n/n)_{n\in\mathbb N} satisfies an LDP with the rate function I~\tilde{I} as in the independent case and not, as one might na{\"i}vely expect, with rate function I2I_2. We relate this fact to the number of solutions of certain Diophantine equations. Our results show that LDPs for lacunary trigonometric sums are sensitive to the arithmetic properties of (ak)kN(a_k)_{k\in\mathbb N}. This is particularly noteworthy since no such arithmetic effects are visible in the central limit theorem by Salem and Zygmund or in the law of the iterated logarithm by Erd\"os and G\'al. Our proofs use a combination of tools from probability theory, harmonic analysis, and dynamical systems.

Keywords

Cite

@article{arxiv.2012.05281,
  title  = {Large Deviation Principles for Lacunary Sums},
  author = {Christoph Aistleitner and Nina Gantert and Zakhar Kabluchko and Joscha Prochno and Kavita Ramanan},
  journal= {arXiv preprint arXiv:2012.05281},
  year   = {2020}
}

Comments

44 pages, 1 figure

R2 v1 2026-06-23T20:51:18.934Z