Pinned geometric configurations in Euclidean space and Riemannian manifolds

Abstract

Let M be a compact d-dimensional Riemannian manifold without a boundary. Given E ⊂ M, let (E)=\(x,y): x,y ∈ E \, where is the Riemannian metric on M. Let x denote the pinned distance set, namely, \(x,y): y ∈ E \ with x ∈ E. We prove that if the Hausdorff dimension of E is greater than d+12, then there exist many x ∈ E such that the Lebesgue measure of x(E) is positive. This result was previously established by Peres and Schlag in the Euclidean setting. The main result is deduced from a variable coefficient Euclidean formulation, which can be used to study a variety of geometric problems. We extend our result to the setting of chains studied in BIT15 and obtain a pinned estimate in this context. Moreover, we point out that our scheme is quite universal in nature and this idea will be exploited in variety of settings in the sequel.