Real interpolation for adapted sequence spaces with variable exponents
Abstract
We study real interpolation for adapted sequence spaces with variable exponents. Let (Ω,F,P;(Fn)n≥ 1) be a filtered complete probability space, let p(·)∈P(Ω), and let 0<q≤∞ and 0<θ<1. We prove that \[ (Ladp(·),Lad∞)θ,q = Ladp(·),q, 1p(·) = 1-θp(·), \] with equivalent quasi-norms. Here Ladp(·),q consists of adapted sequences f=(fn)n≥ 1 whose square function σ(f)=(Σn=1∞|fn|2)1/2 belongs to the variable Lorentz space Lp(·),q. The proof uses a decomposition that preserves adaptedness and provides an upper estimate for the corresponding K-functional. No continuity condition on the variable exponent and no measurability relation between p(·) and the filtration are required.
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