# Two-weight $L^p\to L^q$ bounds for positive dyadic operators in the case   $0<q< 1 \le p<\infty$

**Authors:** Timo S. H\"anninen, Igor E. Verbitsky

arXiv: 1706.08657 · 2017-06-28

## TL;DR

This paper characterizes two-weight inequalities for positive dyadic operators in the challenging range where 0<q<1≤p<∞, introducing potential conditions and applying results to Riesz potentials, relevant for nonlinear PDEs.

## Contribution

It provides a complete characterization of two-weight bounds for positive dyadic operators in the difficult range 0<q<1≤p<∞, including necessary and sufficient conditions and applications to Riesz potentials.

## Key findings

- Characterization of two-weight inequalities for 0<q<1≤p<∞.
- Introduction of scale of discrete Wolff potential conditions.
- Application to Riesz potentials controlled by dyadic operators.

## Abstract

Let $\sigma$, $\omega$ be measures on $\mathbb{R}^d$, and let $\{\lambda_Q\}_{Q\in\mathcal{D}}$ be a family of non-negative reals indexed by the collection $\mathcal{D}$ of dyadic cubes in $\mathbb{R}^d$. We characterize the two-weight norm inequality, \begin{equation*} \lVert T_\lambda(f\sigma)\rVert_{L^q(\omega)}\le C \, \lVert f \rVert_{L^p(\sigma)}\quad \text{for every $f\in L^p(\sigma)$,} \end{equation*} for the positive dyadic operator \begin{equation*} T_\lambda(f\sigma):= \sum_{Q\in \mathcal{D}} \lambda_Q \, \Big(\frac{1}{\sigma(Q)} \int_Q f\mathrm{d}\sigma\Big) \, 1_Q \end{equation*} in the difficult range $0<q<1 \le p<\infty$ of integrability exponents. This range of the exponents $p, q$ appeared recently in applications to nonlinear PDE, which was one of the motivations for our study.   Furthermore, we introduce a scale of discrete Wolff potential conditions that depends monotonically on an integrability parameter, and prove that such conditions are necessary (but not sufficient) for small parameters, and sufficient (but not necessary) for large parameters.   Our characterization applies to Riesz potentials $I_\alpha (f \sigma) = (-\Delta)^{-\frac{\alpha}{2}} (f\sigma) $ ($0<\alpha<d$), since it is known that they can be controlled by model dyadic operators. The weighted norm inequality for Riesz potentials in this range of $p, q$ has been characterized previously only in the special case where $\sigma$ is Lebesgue measure.

## Full text

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## References

26 references — full list in the complete paper: https://tomesphere.com/paper/1706.08657/full.md

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Source: https://tomesphere.com/paper/1706.08657