English

H\"ormander's multiplier theorem for the Dunkl transform

Functional Analysis 2018-07-10 v1

Abstract

For a normalized root system RR in RN\mathbb R^N and a multiplicity function k0k\geq 0 let N=N+αRk(α)\mathbf N=N+\sum_{\alpha \in R} k(\alpha). Denote by dw(x)=αRx,αk(α)dxdw(\mathbf x)=\prod_{\alpha\in R}|\langle \mathbf x,\alpha\rangle|^{k(\alpha)}\, d\mathbf x the associated measure in RN\mathbb R^N. Let F\mathcal F stands for the Dunkl transform. Given a bounded function mm on RN\mathbb R^N, we prove that if there is s>Ns>\mathbf N such that mm satisfies the classical H\"ormander condition with the smoothness ss, then the multiplier operator Tmf=F1(mFf)\mathcal T_mf=\mathcal F^{-1}(m\mathcal Ff) is of weak type (1,1)(1,1), strong type (p,p)(p,p) for 1<p<1<p<\infty, and bounded on a relevant Hardy space H1H^1. To this end we study the Dunkl translations and the Dunkl convolution operators and prove that if FF is sufficiently regular, for example its certain Schwartz class seminorm is finite, then the Dunkl convolution operator with the function FF is bounded on Lp(dw)L^p(dw) for 1p1\leq p\leq \infty. We also consider boundedness of maximal operators associated with the Dunkl convolutions with Schwartz class functions.

Keywords

Cite

@article{arxiv.1807.02640,
  title  = {H\"ormander's multiplier theorem for the Dunkl transform},
  author = {Jacek Dziubański and Agnieszka Hejna},
  journal= {arXiv preprint arXiv:1807.02640},
  year   = {2018}
}
R2 v1 2026-06-23T02:53:33.530Z