Sparse Bounds for Random Discrete Carleson Theorems

Abstract: We study discrete random variants of the Carleson maximal operator. Intriguingly, these questions remain subtle and difficult, even in this setting. Let ${X_m}$ be an independent sequence of ${0,1}$ random variables with expectations [ \mathbb E X_m = \sigma_m = m^{-\alpha}, \ 0 < \alpha < 1/2, ] and $ S_m = \sum_{k=1} ^{m} X_k$. Then the maximal operator below almost surely is bounded from $ \ell ^{p}$ to $ \ell ^{p}$, provided the Minkowski dimension of $ \Lambda \subset [-1/2, 1/2]$ is strictly less than $ 1- \alpha $. [ \sup_{\lambda \in \Lambda } \Bigl| \sum_{m\neq 0} X_{\lvert m\rvert } \frac{e( \lambda m )}{ {\rm sgn} (m)S_{ |m| }} f(x- m) \Bigr|. ] This operator also satisfies a sparse type bound. The form of the sparse bound immediately implies weighted estimates in all $ \ell ^{2}$, which are novel in this setting. Variants and extensions are also considered.