Two weight inequality for vector-valued positive dyadic operators by parallel stopping cubes

Abstract

We study the vector-valued positive dyadic operator \[Tλ(fσ):=ΣQ∈D λQ ∫Q f dσ 1Q,\] where the coefficients \λQ:C D\Q∈D are positive operators from a Banach lattice C to a Banach lattice D. We assume that the Banach lattices C and D* each have the Hardy--Littlewood property. An example of a Banach lattice with the Hardy--Littlewood property is a Lebesgue space. In the two-weight case, we prove that the LpC(σ) LqD(ω) boundedness of the operator Tλ( · σ) is characterized by the direct and the dual L∞ testing conditions: \[ 1Q Tλ(1Q f σ)LqD(ω) fL∞C(Q,σ) σ(Q)1/p,\] \[ 1Q T*λ(1Q g ω)Lp'C*(σ) gL∞D*(Q,ω) ω(Q)1/q'.\] Here LpC(σ) and LqD(ω) denote the Lebesgue--Bochner spaces associated with exponents 1<p≤ q<∞, and locally finite Borel measures σ and ω. In the unweighted case, we show that the LpC(μ) LpD(μ) boundedness of the operator Tλ( · μ) is equivalent to the endpoint direct L∞ testing condition: \[ 1Q Tλ(1Q f μ)L1D(μ) fL∞C(Q,μ) μ(Q).\] This condition is manifestly independent of the exponent p. By specializing this to particular cases, we recover some earlier results in a unified way.