English

Generalised Flatness Constants: A Framework Applied in Dimension $2$

Metric Geometry 2021-10-07 v1 Combinatorics Symplectic Geometry

Abstract

Let A{Z,R}A \in \{ \mathbb{Z}, \mathbb{R} \} and XRdX \subset \mathbb{R}^d be a bounded set. Affine transformations given by an automorphism of Zd\mathbb{Z}^d and a translation in AdA^d are called (affine) AA-unimodular transformations. The image of XX under such a transformation is called an AA-unimodular copy of XX. It was shown in [Averkov, Hofscheier, Nill, 2019] that every convex body whose width is "big enough" contains an AA-unimodular copy of XX. The threshold when this happens is called the generalised flatness constant FltdA(X)\mathrm{Flt}_d^A(X). It resembles the classical flatness constant if A=ZA=\mathbb{Z} and XX is a lattice point. In this work, we introduce a general framework for the explicit computation of these numerical constants. The approach relies on the study of AA-XX-free convex bodies generalising lattice-free (also known as hollow) convex bodies. We then focus on the case that X=PX=P is a full-dimensional polytope and show that inclusion-maximal AA-PP-free convex bodies are polytopes. The study of those inclusion-maximal polytopes provides us with the means to explicitly determine generalised flatness constants. We apply our approach to the case X=Δ2X=\Delta_2 the standard simplex in R2\mathbb{R}^2 of normalised volume 11 and compute Flt2R(Δ2)=2\mathrm{Flt}^{\mathbb{R}}_2(\Delta_2)=2 and Flt2Z(Δ2)=103\mathrm{Flt}^{\mathbb{Z}}_2(\Delta_2)=\frac{10}3.

Keywords

Cite

@article{arxiv.2110.02770,
  title  = {Generalised Flatness Constants: A Framework Applied in Dimension $2$},
  author = {Giulia Codenotti and Thomas Hall and Johannes Hofscheier},
  journal= {arXiv preprint arXiv:2110.02770},
  year   = {2021}
}
R2 v1 2026-06-24T06:40:15.640Z