Shiwen Zhang
In this paper, we study the Favard length of some random Cantor sets of Hausdorff dimension 1. We start with a unit disk in the plane and replace the unit disk by 4 disjoint subdisks (with equal distance to each other) of radius 1/4 inside and tangent to the unit disk. By repeating this operation in a self-similar manner and adding a random rotation in each step, we can generate a random Cantor set D(ω). Let Dn be the n-th generation in the construction, which is comparable to the 4−n-neighborhood of D. We are interested in the decay rate of the Favard length of these sets Dn as n→∞, which is the likelihood (up to a constant) that "Buffon's needle'' dropped randomly will fall into the 4−n-neighborhood of D. It is well known that the lower bound of the Favard length of Dn(ω) is a constant multiple of n−1. We show that the upper bound of the Favard length of Dn(ω) is Cn−1 for some C>0 in the average sense. We also prove the a similar linear decay for the Favard length of Ddn(ω), which is the d−n-neighborhood of a self-similar random Cantor set with degree d greater than 4. Notice that in the non-random case where the self-similar set has degree greater than 4, the best known result for the decay rate of the Favard length is e−clogn√.
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