On Convergence of Oscillatory Ergodic Hilbert Transforms

Abstract

We introduce sufficient conditions on discrete singular integral operators for their maximal truncations to satisfy a sparse bound. The latter imply a range of quantitative weighted inequalities, which are new. As an application, we prove the following ergodic theorem: let p(t) be a Hardy field function which grows "super-linearly" and stays "sufficiently far" from polynomials. We show that for each measure-preserving system, (X,,μ,τ), with τ a measure-preserving Z-action, the modulated one-sided ergodic Hilbert transform \[ Σn=1∞ e2π i p(n)n τn f(x) \] converges μ-a.e. for each f ∈ Lr(X), \ 1 ≤ r < ∞. This affirmatively answers a question of J. Rosenblatt. In the second part of the paper, we establish almost sure sparse bounds for random one-sided ergodic Hilbert transforms, \[ Σn=1∞ Xnn τn f(x), \] where \ Xn \ are uniformly bounded, independent, and mean-zero random variables.