Banach actions preserving unconditional convergence

Abstract

Let A,X,Y be Banach spaces and A× X Y, (a,x) ax, be a continuous bilinear function, called a *Banach action*. We say that this action *preserves unconditional convergence* if for every bounded sequence (an)n∈ω in A and unconditionally convergent series Σn∈ωxn in X the series Σn∈ωanxn is unconditionally convergent. We prove that a Banach action A× X Y preserves unconditional convergence if and only if for any linear functional y*∈ Y* the operator Dy*:X A*, Dy*(x)(a)=y*(ax), is absolutely summing. Combining this characterization with the famous Grothendieck theorem on the absolute summability of operators from 1 to 2, we prove that a Banach action A× X Y preserves unconditional convergence if A is a Hilbert space possessing an orthonormal basis (en)n∈ω such that for every x∈ X the series Σn∈ωenx is weakly absolutely convergent. Applying known results of Garling on the absolute summability of diagonal operators between sequence spaces, we prove that for (finite or infinite) numbers p,q,r∈[1,∞] with 1r1p+1q, the coordinatewise multplication p×qr preserves unconditional convergence if and only if one of the following conditions holds: (i) p 2 and q r, (ii) 2<p<q r, (iii) 2<p=q<r, (iv) r=∞, (v) 2 q<p r, (vi) q<2<p and 1p+1q1r+12.