Schur-type Banach modules of integral kernels acting on mixed-norm Lebesgue spaces

Abstract

Schur's test states that if K:X× Y satisfies ∫Y |K(x,y)|d(y)≤ C and ∫X |K(x,y)|dμ(x)≤ C, then the associated integral operator acts boundedly on Lp for all p∈ [1,∞]. We derive a variant of this result ensuring boundedness on the (weighted) mixed-norm Lebesgue spaces Lwp,q for all p,q∈ [1,∞]. For non-negative integral kernels our criterion is sharp; i.e., it is satisfied if and only if the integral operator acts boundedly on all of the mixed-norm Lebesgue spaces. Motivated by this criterion, we introduce solid Banach modules Bm(X,Y) of integral kernels such that all kernels in Bm(X,Y) map Lwp,q() boundedly into Lvp,q(μ) for all p,q ∈ [1,∞], provided that the weights v,w are m-moderate. Conversely, if A and B are solid Banach spaces for which all kernels K∈Bm(X,Y) map A into B, then A and B are related to mixed-norm Lebesgue-spaces; i.e., (L1 L∞ L1,∞ L∞,1)vB and A(L1 + L∞ + L1,∞ + L∞,1)1/w for certain weights v,w depending on the weight m. The kernel algebra Bm(X,X) is particularly suited for applications in (generalized) coorbit theory: Usually, a host of technical conditions need to be verified to guarantee that coorbit space theory is applicable for a given continuous frame and a Banach space A. We show that it is enough to check that certain integral kernels associated to belong to Bm(X,X); this ensures that the coorbit spaces Co (Lp,q) are well-defined for all p,q∈ [1,∞] and all weights compatible with m.