# On Lattice Diameter Segments and A Discrete Borsuk Partition Problem

**Authors:** Anouk E. Brose, Jes\'us A. De Loera, Gyivan Lopez-Campos, Antonio J. Torres

arXiv: 2508.20009 · 2025-08-29

## TL;DR

This paper investigates the properties of lattice diameter segments in sets within Euclidean space, providing algorithms, complexity results, and a Borsuk-type partition theorem relevant to discrete geometry.

## Contribution

It introduces a polynomial-time algorithm for lattice polygons, proves NP-hardness for higher dimensions, and establishes a Borsuk-type theorem for lattice point partitions.

## Key findings

- Polynomial-time algorithm for lattice polygons
- NP-hardness of computing lattice diameters in higher dimensions
- Lattice diameter segment count is eventually a quasi-polynomial

## Abstract

The lattice diameter of a bounded set $S \subset \mathbb{R}^d$ measures the maximal number of lattice points in a segment whose endpoints are lattice points in $S$. Such a segment is called a lattice diameter segment of $S$. This simple invariant yields interesting applications and challenges. We describe a polynomial-time algorithm that computes lattice diameter segments of lattice polygons and show that computing lattice diameters of semi-algebraic sets in dimensions three and higher is NP-hard. We prove that the function that counts lattice diameter segments in dilations of a lattice polygon is eventually a quasi-polynomial in the dilation factor. We also study the number of directions that lattice diameter segments can have. Finally, we prove a Borsuk-type theorem on the number of parts needed to partition a set of lattice points such that each part has strictly smaller lattice diameter.

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Source: https://tomesphere.com/paper/2508.20009