English

Generalized Hilbert Operator Acting on Hardy Spaces

Functional Analysis 2025-02-19 v2

Abstract

Let α>0\alpha>0 and μ\mu be a positive Borel measure on the interval [0,1)[0,1). The Hankel matrix Hμ,α=(μn,k,α)n,k0\mathcal{H}_{\mu,\alpha}=(\mu_{n,k,\alpha})_{n,k\ge0} with entries μn,k,α=[0,1)Γ(n+α)Γ(n+1)Γ(α)tn+kdμ(t)\mu_{n,k,\alpha}=\int_{[0,1)}^{}\frac{\Gamma(n+\alpha)}{\Gamma(n+1)\Gamma(\alpha)}t^{n+k}d\mu(t), induces, formally, the generalized-Hilbert operator as Hμ,α(f)(z)=n=0(k=0μn,k,αak)zn,zD \mathcal{H}_{\mu,\alpha}\left ( f \right ) \left ( z \right ) =\sum_{n=0}^{\infty} \left (\sum_{k=0}^{\infty} \mu_{n,k,\alpha}a_k \right )z^n,z\in\mathbb{D} where f(z)=k=0akzkf(z)={\textstyle \sum_{k=0}^{\infty }} a_kz^k is an analytic function in D\mathbb{D}. This article is devoted study the measures μ\mu for which Hμ,α\mathcal{H}_{\mu,\alpha } is a bounded(resp., compact) operator from Hp(0<p1)H^p(0<p\le1) into Hp(1q<)H^p(1\le q<\infty). Then, we also study the analogous problem in the Hardy spaces Hp(1p2)H^p(1\le p\le2). Finally, we obtain the essential norm of Hμ,α\mathcal{H}_{\mu,\alpha} from Hp(0<p1)H^p(0<p\le1) into Hp(1q<)H^p(1\le q<\infty).

Keywords

Cite

@article{arxiv.2410.20435,
  title  = {Generalized Hilbert Operator Acting on Hardy Spaces},
  author = {Huiling Chen and Shanli Ye},
  journal= {arXiv preprint arXiv:2410.20435},
  year   = {2025}
}
R2 v1 2026-06-28T19:37:07.746Z