Quantitative Hardy--Littlewood maximal inequalities and Wiener--Stein theorem on fractal sets (2506.07382v1)

Abstract: Let $K\subset \mathbb{R}^d$ be a self-similar set with Hausdorff dimension $s$, and $\mu$ be a self-similar probability measure supported on $K$. Let $H^{\alpha}_\mu$, $0<\alpha\le s$, be the Hausdorff content on $K$, and $M_{\mathcal{D}}^\mu $ be the Hardy--Littlewood maximal operator defined on $K$ associated with its basic cubes $\mathcal{D}$. In this paper, we establish quantitative strong type and weak type Hardy--Littlewood maximal inequalities on fractal set $K$ with respect to $H^{\alpha}_\mu$ for all range $0<\alpha\le s$. As applications, the Lebesgue differentiation theorem on $K$ is proved. Moreover, via the Hardy--Littlewood maximal operator $M_{\mathcal{D}}^\mu $, we characterize the Lebesgue--Choquet space $L^p(K,H^{\alpha}_\mu)$ and the Zygmund space $L\log L(K,\mu)$. To be exact, given $\alpha/s< p\le \infty$, we discover that [ \text{$f\in L^p(K,H^{\alpha}_\mu)$ if and only if $M_{\mathcal{D}}^\mu f\in L^p(K,H^{\alpha}_\mu)$}] and, for $f\in L^1(K,\mu)$, [\text{$M_{\mathcal{D}}^\mu f\in L^1(K,\mu)$ if and only if $f\in L\log L(K,\mu)$}. ] That is, Wiener's $L\log L$ inequality and its converse inequality due to Stein in 1969 are extended to fractal set $K$ with respect to $\mu$.