English

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

Classical Analysis and ODEs 2014-09-23 v2

Abstract

Let us say that an element of a given family \A\A of subsets of Rd\R^d can be reconstructed using nn test sets if there exist T1,...,TnRdT_1,...,T_n \subset \R^d such that whenever A,B\AA,B\in \A and the Lebesgue measures of ATiA \cap T_i and BTiB \cap T_i agree for each i=1,...,ni=1,...,n then A=BA=B. Our goal will be to find the least such nn. We prove that if \A\A consists of the translates of a fixed reasonably nice subset of Rd\R^d then this minimum is n=dn=d. In order to obtain this result we reconstruct a translate of a fixed function using dd test sets as well, and also prove that under rather mild conditions the measure function fK,θ(r)=\lad1(K{x\RRd:<x,θ>=r})f_{K,\theta} (r) = \la^{d-1} (K \cap \{x \in \RR^d : <x,\theta> = r\}) of the sections of KK is absolutely continuous for almost every direction θ\theta. These proofs are based on techniques of harmonic analysis. We also show that if \A\A consists of the magnified copies rE+trE+t (r1,tRd)(r\ge 1, t\in\R^d) of a fixed reasonably nice set ERdE\subset \R^d, where d2d\ge 2, then d+1d+1 test sets reconstruct an element of \A\A. This fails in R\R: 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 kk-dimensional family of geometric objects can be reconstructed using 2k+12k+1 test sets. A example from algebraic topology shows that 2k+12k+1 is sharp in general.

Keywords

Cite

@article{arxiv.1109.6169,
  title  = {Reconstructing geometric objects from the measures of their intersections with test sets},
  author = {Márton Elekes and Tamás Keleti and András Máthé},
  journal= {arXiv preprint arXiv:1109.6169},
  year   = {2014}
}
R2 v1 2026-06-21T19:11:40.124Z