English

Summability of multilinear forms on classical sequence spaces

Functional Analysis 2016-04-07 v1

Abstract

We present an extension of the Hardy--Littlewood inequality for multilinear forms. More precisely, let K\mathbb{K} be the real or complex scalar field and m,km,k be positive integers with mkm\geq k\, and n1,,nkn_{1},\dots ,n_{k} be positive integers such that n1++nk=mn_{1}+\cdots +n_{k}=m. (aa) If (r,p)(0,)×[2m,](r,p)\in (0,\infty )\times \lbrack 2m,\infty ] then there is a constant Dm,r,p,kK1D_{m,r,p,k}^{\mathbb{K}}\geq 1 (not depending on nn) such that \left( \sum_{i_{1},\dots ,i_{k}=1}^{n}\left| T\left( e_{i_{1}}^{n_{1}},\dots ,e_{i_{k}}^{n_{k}}\right) \right| ^{r}\right) ^{% \frac{1}{r}}\leq D_{m,r,p,k}^{\mathbb{K}} \cdot n^{max\left\{ \frac{% 2kp-kpr-pr+2rm}{2pr},0\right\} }\left| T\right| for all mm-linear forms T:pn××pnKT:\ell_{p}^{n}\times \cdots \times \ell_{p}^{n}\rightarrow \mathbb{K} and all positive integers nn. Moreover, the exponent max{2kpkprpr+2rm2pr,0}max\left\{ \frac{2kp-kpr-pr+2rm}{2pr},0\right\} is optimal. (bb) If (r,p)(0,)×(m,2m](r, p) \in (0, \infty) \times (m, 2m] then there is a constant % D_{m,r,p, k}^{\mathbb{K}}\geq 1 (not depending on nn) such that \left( \sum_{i_{1},\dots ,i_{k}=1}^{n }\left| T\left( e_{i_{1}}^{n_{1}},\dots ,e_{i_{k}}^{n_{k}}\right) \right| ^{r }\right) ^{% \frac{1}{r }}\leq D_{m,r,p, k}^{\mathbb{K}} \cdot n^{ max \left\{\frac{% p-rp+rm}{pr}, 0\right\}}\left| T\right| for all mm-linear forms T:pn××pnKT:\ell_{p}^{n}\times \cdots \times \ell_{p}^{n}\rightarrow \mathbb{K} and all positive integers nn. Moreover, the exponent max{prp+rmpr,0}max \left\{\frac{p-rp+rm}{pr}, 0\right\} is optimal. The case k=mk=m recovers a recent result due to G. Araujo and D. Pellegrino.

Keywords

Cite

@article{arxiv.1604.01610,
  title  = {Summability of multilinear forms on classical sequence spaces},
  author = {Tony Nogueira and Pilar Rueda},
  journal= {arXiv preprint arXiv:1604.01610},
  year   = {2016}
}
R2 v1 2026-06-22T13:26:28.759Z