English

Interpolating with generalized Assouad dimensions

Classical Analysis and ODEs 2025-07-10 v2 Dynamical Systems Metric Geometry Probability

Abstract

The ϕ\phi-Assouad dimensions are a family of dimensions which interpolate between the upper box and Assouad dimensions. They are a generalization of the well-studied Assouad spectrum with a more general form of scale sensitivity that is often closely related to "phase-transition" phenomena in sets. In this article we establish a number of key properties of the ϕ\phi-Assouad dimensions which help to clarify their behaviour. We prove for any bounded doubling metric space FF and αR\alpha\in\mathbb{R} satisfying dimBF<αdimAF\overline{\operatorname{dim}}_{\mathrm{B}}F<\alpha\leq\operatorname{dim}_{\mathrm{A}} F that there is a function ϕ\phi so that the ϕ\phi-Assouad dimension of FF is equal to α\alpha. We further show that the "upper" variant of the dimension is fully determined by the ϕ\phi-Assouad dimension, and that homogeneous Moran sets are in a certain sense generic for these dimensions. Further, we study explicit examples of sets where the Assouad spectrum does not reach the Assouad dimension. We prove a precise formula for the ϕ\phi-Assouad dimensions for Galton--Watson trees that correspond to a general class of stochastically self-similar sets, including Mandelbrot percolation. This result follows from two results which may be of general interest: a sharp large deviations theorem for Galton--Watson processes with bounded offspring distribution, and a Borel--Cantelli-type lemma for infinite structures in random trees. Finally, we obtain results on the ϕ\phi-Assouad dimensions of overlapping self-similar sets and decreasing sequences with decreasing gaps.

Keywords

Cite

@article{arxiv.2308.12975,
  title  = {Interpolating with generalized Assouad dimensions},
  author = {Amlan Banaji and Alex Rutar and Sascha Troscheit},
  journal= {arXiv preprint arXiv:2308.12975},
  year   = {2025}
}

Comments

54 pages, 2 figures. Numbering changed from v1; Theorem E, Theorem 4.7, and Theorem 4.10 (with the new numbering) have been corrected. To appear in the Journal of Geometric Analysis

R2 v1 2026-06-28T12:03:44.426Z