Medians, Oscillations, and Distance Functions

Abstract

We establish a geometric characterization of the sets $E \subset \mathbb{R}^n$ so that the corresponding log-distance function $\log \text{dist}(\cdot, E)$ is in $BMO$ (or equivalently $\text{dist}(\cdot, E)^{-\alpha} \in A_\infty$ for some $\alpha > 0$), generalizing the $A_1$ characterization in the work by Anderson, Lehrb\"ack, Mudarra, and V\"ah\"akangas. The proof relies on a new median-value characterization of $BMO$: For a real-valued measurable function on $\mathbb{R}^n$ and constants $0 < s < t < 1$, \[\|f\|_{BMO} \approx_{s, t, n} \sup_{Q}[M_t(f, Q) - M_s(f, Q)]\] where $M_s(f, Q)$ denotes the $s$-median value of $f$ on $Q$. We apply our characterization to the study of Hardy-Sobolev inequalities.

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