Christoph Aistleitner
Published 2012-11-20Version 1
Bourgain posed the problem of calculating $$ \Sigma = \sup_{n \geq 1} ~\sup_{k_1 <... < k_n} \frac{1}{\sqrt{n}}\| \sum_{j=1}^n e^{2 \pi i k_j \theta}\|_{L^1([0,1])}. $$ It is clear that $\Sigma \leq 1$; beyond that, determining whether $\Sigma < 1$ or $\Sigma=1$ would have some interesting implications, for example concerning the problem whether all rank one transformations have singular maximal spectral type. In the present paper we prove $\Sigma \geq \sqrt{\pi}/2 \approx 0.886$, by this means improving a result of Karatsuba. For the proof we use a quantitative two-dimensional version of the central limit theorem for lacunary trigonometric series, which in its original form is due to Salem and Zygmund.
Exponential sums with coefficients 0 or 1 and concentrated L^{p} norms
Uniform oscillatory behavior of spherical functions of $GL_n/U_n$ at the identity and a central limit theorem
Yet another note on the arithmetic-geometric mean inequality
![QR code for arXiv:1211.4640 [math.CA]](http://oss.arxitics.com/images/favicon.svg)