Metric number theory, lacunary series and systems of dilated functions

Abstract

By a classical result of Weyl, for any increasing sequence (nk)k ≥ 1 of integers the sequence of fractional parts (\nk x\)k ≥ 1 is uniformly distributed modulo 1 for almost all x ∈ [0,1]. Except for a few special cases, e.g. when nk=k, k ≥ 1, the exceptional set cannot be described explicitly. The exact asymptotic order of the discrepancy of (\nk x\)k ≥ 1 is only known in a few special cases, for example when (nk)k ≥ 1 is a (Hadamard) lacunary sequence, that is when nk+1/nk ≥ q > 1, k ≥ 1. In this case of quickly increasing (nk)k ≥ 1 the system (\nk x\)k ≥ 1 (or, more general, (f(nk x))k ≥ 1 for a 1-periodic function f) shows many asymptotic properties which are typical for the behavior of systems of independent random variables. Precise results depend on a fascinating interplay between analytic, probabilistic and number-theoretic phenomena. Without any growth conditions on (nk)k ≥ 1 the situation becomes much more complicated, and the system (f(nk x))k ≥ 1 will typically fail to satisfy probabilistic limit theorems. An important problem which remains is to study the almost everywhere convergence of series Σk=1∞ ck f(k x), which is closely related to finding upper bounds for maximal L2-norms of the form ∫01 (1 ≤ M ≤ N| Σk=1M ck f(kx)|2 dx. The most striking example of this connection is the equivalence of the Carleson convergence theorem and the Carleson--Hunt inequality for maximal partial sums of Fourier series. For general functions f this is a very difficult problem, which is related to finding upper bounds for certain sums involving greatest common divisors.