Finite Point Configurations and the Regular Value Theorem in a Fractal setting

Abstract

In this article, we study two problems concerning the size of the set of finite point configurations generated by a compact set E⊂ Rd. The first problem concerns how the Lebesgue measure or the Hausdorff dimension of the finite point configuration set depends on that of E. In particular, we show that if a planar set has dimension exceeding 54, then there exists a point x∈ E so that for each integer k≥2, the set of "k-chains" with initial point at x has positive Lebesgue measure. The second problem is a continuous analogue of the Erdos unit distance problem, which aims to determine the maximum number of times a point configuration with prescribed gaps can appear in E. For instance, given a triangle with prescribed sides and given a sufficiently regular planar set E with Hausdorff dimension no less than 74, we show that the dimension of the set of vertices in E forming said triangle does not exceed 3\,H (E)-3. In addition to the Euclidean norm, we consider more general distances given by functions satisfying the so-called Phong-Stein rotational curvature condition. We also explore a number of examples to demonstrate the extent to which our results are sharp.