Sparse Bounds for Maximal Monomial Oscillatory Hilbert Transforms
arXiv:1609.01564
Abstract
For each $ d \geq 2$, the Hilbert transform with a polynomial oscillation as below satisfies a $ (1, r )$ sparse bound, for all $ r>1$ $$ H _{ \ast } f (x) = \sup _{ε} \Bigl\lvert \int_{|y| > ε} f (x-y) \frac { e ^{2 Ïi y ^d }} y\; dy \Bigr\rvert. $$ This quickly implies weak-type inequalities for the maximal truncations, which hold for $A_1$ weights, but are new even in the case of Lebesgue measure. The unweighted weak-type estimate \emph{without maximal truncations} but with arbitrary polynomials, is due to Chanillo and Christ (1987).
12 pages. v2 proves the sparse bounds. Accepted to Studia Math