Reconstructing geometric objects from the measures of their intersections with test sets

Abstract

Let us say that an element of a given family of subsets of d can be reconstructed using n test sets if there exist T1,...,Tn ⊂ d such that whenever A,B∈ and the Lebesgue measures of A Ti and B Ti agree for each i=1,...,n then A=B. Our goal will be to find the least such n. We prove that if consists of the translates of a fixed reasonably nice subset of d then this minimum is n=d. In order to obtain this result we reconstruct a translate of a fixed function using d test sets as well, and also prove that under rather mild conditions the measure function fK,θ (r) = d-1 (K \x ∈ d : <x,θ> = r\) of the sections of K is absolutely continuous for almost every direction θ. These proofs are based on techniques of harmonic analysis. We also show that if consists of the magnified copies rE+t (r 1, t∈d) of a fixed reasonably nice set E⊂ d, where d 2, then d+1 test sets reconstruct an element of . This fails in : we prove that an interval, and even an interval of length at least 1 cannot be reconstructed using 2 test sets. Finally, using randomly constructed test sets, we prove that an element of a reasonably nice k-dimensional family of geometric objects can be reconstructed using 2k+1 test sets. A example from algebraic topology shows that 2k+1 is sharp in general.