A sharp threshold for arithmetic effects on the tail probabilities of lacunary sums
Abstract
A classical observation in analysis asserts that lacunary systems of dilated functions show many properties which are also typical for systems of independent random variables. For example, if (nk)k 1 is a sequence of integers satisfying the Hadamard gap condition nk+1/nk q > 1,~k 1, then the normalized sums Σn=1N (2π nk x), considered on the probability space [0,1] with Borel σ-field and Lebesgue measure, satisfy the central limit theorem (CLT) and the law of the iterated logarithm (LIL). Remarkably, the situation becomes much more deliacate when the trigonometric function (2 π x) is replaced by a more general 1-periodic function f, and fine arithmetic properties of the sequence (nk)k 1 come into play. The most relevant arithmetic property can be phrased in terms of the number of solutions of certain 2-variable Diophantine equations. Recently, the authors proved that the validity of the LIL requires a strictly stronger Diophantine criterion than the CLT. In the present paper we show that this is only a special case of a wide-ranging general principle: there is a sharp cutoff, which can be expressed in form of a Diophantine criterion on the sequence (nk)k 1, at which the tail probabilities of Σk=1N f(nk x) change from Gaussian to potentially erratic behavior. More precisely, let L(N,a,b,c) be the number of solutions (k,) of the equation a nk - b n= c, where 1≤ k, ≤ N. Roughly speaking, we prove: if L(N,a,b,c) N / gN for some gN, then P [Σk=1N f(nk x) > t \|f\|2 N ] is asymptotically is accordance with standard normal behavior for all t up to 2 gN. We also show that this criterion is optimal in the sense that under the same premises, the conclusion can fail to be true for values of t beyond this threshold.
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