Search citation statements
Paper Sections
Citation Types
Year Published
Publication Types
Relationship
Authors
Journals
Cited by 14 publications
References 17 publications
In this paper we consider the following problem: let Xk, be a Banach space with a normalised basis (e(k, j))j, whose biorthogonals are denoted by ${(e_{(k,j)}^*)_j}$ , for $k\in\N$ , let $Z=\ell^\infty(X_k:k\kin\N)$ be their l∞-sum, and let $T:Z\to Z$ be a bounded linear operator with a large diagonal, i.e., $$\begin{align*}\inf_{k,j} \big|e^*_{(k,j)}(T(e_{(k,j)})\big|>0.\end{align*}$$ Under which condition does the identity on Z factor through T? The purpose of this paper is to formulate general conditions for which the answer is positive.
In this paper we consider the following problem: let Xk, be a Banach space with a normalised basis (e(k, j))j, whose biorthogonals are denoted by ${(e_{(k,j)}^*)_j}$ , for $k\in\N$ , let $Z=\ell^\infty(X_k:k\kin\N)$ be their l∞-sum, and let $T:Z\to Z$ be a bounded linear operator with a large diagonal, i.e., $$\begin{align*}\inf_{k,j} \big|e^*_{(k,j)}(T(e_{(k,j)})\big|>0.\end{align*}$$ Under which condition does the identity on Z factor through T? The purpose of this paper is to formulate general conditions for which the answer is positive.
Multipliers on bi-parameter Haar system Hardy spaces
Let $$(h_I)$$ ( h I ) denote the standard Haar system on [0, 1], indexed by $$I\in \mathcal {D}$$ I ∈ D , the set of dyadic intervals and $$h_I\otimes h_J$$ h I ⊗ h J denote the tensor product $$(s,t)\mapsto h_I(s) h_J(t)$$ ( s , t ) ↦ h I ( s ) h J ( t ) , $$I,J\in \mathcal {D}$$ I , J ∈ D . We consider a class of two-parameter function spaces which are completions of the linear span $$\mathcal {V}(\delta ^2)$$ V ( δ 2 ) of $$h_I\otimes h_J$$ h I ⊗ h J , $$I,J\in \mathcal {D}$$ I , J ∈ D . This class contains all the spaces of the form X(Y), where X and Y are either the Lebesgue spaces $$L^p[0,1]$$ L p [ 0 , 1 ] or the Hardy spaces $$H^p[0,1]$$ H p [ 0 , 1 ] , $$1\le p < \infty $$ 1 ≤ p < ∞ . We say that $$D:X(Y)\rightarrow X(Y)$$ D : X ( Y ) → X ( Y ) is a Haar multiplier if $$D(h_I\otimes h_J) = d_{I,J} h_I\otimes h_J$$ D ( h I ⊗ h J ) = d I , J h I ⊗ h J , where $$d_{I,J}\in \mathbb {R}$$ d I , J ∈ R , and ask which more elementary operators factor through D. A decisive role is played by the Capon projection$$\mathcal {C}:\mathcal {V}(\delta ^2)\rightarrow \mathcal {V}(\delta ^2)$$ C : V ( δ 2 ) → V ( δ 2 ) given by $$\mathcal {C} h_I\otimes h_J = h_I\otimes h_J$$ C h I ⊗ h J = h I ⊗ h J if $$|I|\le |J|$$ | I | ≤ | J | , and $$\mathcal {C} h_I\otimes h_J = 0$$ C h I ⊗ h J = 0 if $$|I| > |J|$$ | I | > | J | , as our main result highlights: Given any bounded Haar multiplier $$D:X(Y)\rightarrow X(Y)$$ D : X ( Y ) → X ( Y ) , there exist $$\lambda ,\mu \in \mathbb {R}$$ λ , μ ∈ R such that $$\begin{aligned} \lambda \mathcal {C} + \mu ({{\,\textrm{Id}\,}}-\mathcal {C})\text { approximately 1-projectionally factors through }D, \end{aligned}$$ λ C + μ ( Id - C ) approximately 1-projectionally factors through D , i.e., for all $$\eta > 0$$ η > 0 , there exist bounded operators A, B so that AB is the identity operator $${{\,\textrm{Id}\,}}$$ Id , $$\Vert A\Vert \cdot \Vert B\Vert = 1$$ ‖ A ‖ · ‖ B ‖ = 1 and $$\Vert \lambda \mathcal {C} + \mu ({{\,\textrm{Id}\,}}-\mathcal {C}) - ADB\Vert < \eta $$ ‖ λ C + μ ( Id - C ) - A D B ‖ < η . Additionally, if $$\mathcal {C}$$ C is unbounded on X(Y), then $$\lambda = \mu $$ λ = μ and then $${{\,\textrm{Id}\,}}$$ Id either factors through D or $${{\,\textrm{Id}\,}}-D$$ Id - D .
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
