From Complex-Analytic Models to Dyadic Methods: A Real-Variable Approach to Hypersingular Operators
Abstract
Motivated by the work of Cheng-Fang-Wang-Yu on the hypersingular Bergman projection, we develop a real-variable framework for hypersingular operators in regimes where strong-type bounds fail on the critical line. Our main new ingredient is the Forelli-Rudin method: a dyadic mechanism, inspired by complex-analytic Forelli-Rudin type arguments, that yields sharp critical-line and endpoint estimates. On the unit disc, for , we give a complete -mapping characterization for the dyadic hypersingular maximal operator , including sharp bounds on the critical line and a weighted endpoint criterion in the radial setting. We also prove a novel two-weight estimate for in the range , valid for all . For the hypersingular Bergman projection we establish sharp critical-line bounds, with emphasis on the endpoint weak-type estimate at . In particular, this result resolves an open question on the critical-line behavior of the Bergman projection in the hypersingular regime. Finally, we introduce a class of hypersingular cousins of sparse operators in associated with graded sparse families, quantified by the sparseness and a new structural parameter (the degree) . We characterize the corresponding sharp strong- and weak-type regimes in terms of . This real-variable perspective addresses an inquiry of Cheng-Fang-Wang-Yu on developing effective real-analytic tools in the hypersingular regime for both and , and it also provides a new route to critical-line analysis for Forelli-Rudin type and related hypersingular operators in both real and complex settings.
Keywords
Cite
@article{arxiv.2512.24972,
title = {From Complex-Analytic Models to Dyadic Methods: A Real-Variable Approach to Hypersingular Operators},
author = {Bingyang Hu and Xiaojing Zhou},
journal= {arXiv preprint arXiv:2512.24972},
year = {2026}
}
Comments
37 pages, 3 figures. Refine the main results by establishing the sharpness of the estimates. Comments are welcome!