Quantitative Hardy--Littlewood maximal inequalities and Wiener--Stein theorem on p.c.f. fractals

Abstract

Let K⊂ Rd be a post-critically finite (p.c.f.) self-similar set with Hausdorff dimension s, and μ be a self-similar probability measure supported on K. Let Hαμ, 0<α s, be the Hausdorff content on K, and MDμ be the Hardy--Littlewood maximal operator defined on K associated with its basic cubes D. In this paper, we establish quantitative strong type and weak type Hardy--Littlewood maximal inequalities on fractal set K with respect to Hαμ for all range 0<α s. As applications, the Lebesgue differentiation theorem on K is proved. Moreover, via the Hardy--Littlewood maximal operator MDμ , we characterize the Lebesgue--Choquet space Lp(K,Hαμ) and the Zygmund space L L(K,μ). To be exact, given α/s< p ∞, we discover that \[ f∈ Lp(K,Hαμ) if and only if MDμ f∈ Lp(K,Hαμ)\] and, for f∈ L1(K,μ) with K satisfying the strong separation condition, \[MDμ f∈ L1(K,μ) if and only if f∈ L L(K,μ).\] That is, Wiener's L L inequality and its converse inequality due to Stein in 1969 are extended to fractal set K with respect to μ.