The dimension of random subsets of self-similar sets generated by branching random walk
Abstract
Given a self-similar set Λ that is the attractor of an iterated function system (IFS) \f1,…,fN\, consider the following method for constructing a random subset of Λ: Let p=(p1,…,pN) be a probability vector, and label all edges of a full M-ary tree independently at random with a number from \1,2,…,N\ according to p, where M≥ 2 is an arbitrary integer. Then each infinite path in the tree starting from the root receives a random label sequence which is the coding of a point in Λ. We let F⊂Λ denote the set of all points obtained in this way. This construction was introduced by Allaart and Jones [J. Fractal Geom. 12 (2025), 67--92], who considered the case of a homogeneous IFS on R satisfying the Open Set Condition (OSC) and proved non-trivial upper and lower bounds for the Hausdorff dimension of F. We demonstrate that under the OSC, the Hausdorff (and box-counting) dimension of F is equal to the upper bound of Allaart and Jones, and extend the result to higher dimensions as well as to non-homogeneous self-similar sets.
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