# On Some Problems Related to a Simplex and a Ball

**Authors:** Mikhail Nevskii

arXiv: 1905.01937 · 2020-02-25

## TL;DR

This paper explores geometric relations involving the minimal scaling factors of a convex body, specifically the Euclidean ball, within simplices, extending previous work on convex bodies like the cube.

## Contribution

It extends earlier formulas for convex bodies to the Euclidean ball, providing new relations and geometric interpretations for minimal containment and translation factors.

## Key findings

- Derived new bounds for $\xi(B_n;S)$ and $\alpha(B_n;S)$.
- Established geometric interpretations of these minimal factors.
- Extended previous formulas from cubes to Euclidean balls.

## Abstract

Let $C$ be a convex body and let $S$ be a nondegenerate simplex in ${\mathbb R}^n$. Denote by $\xi(C;S)$ the minimal $\tau>0$ such that $C$ is a subset of the simplex $\tau S$. By $\alpha(C;S)$ we mean the minimal $\tau>0$ such that $C$ is contained in a translate of $\tau S$. Earlier the author has proved the equalities $\xi(C;S)=(n+1)\max\limits_{1\leq j\leq n+1} \max\limits_{x\in C}(-\lambda_j(x))+1$ \ (if $C\not\subset S$), \ $\alpha(C;S)= \sum\limits_{j=1}^{n+1} \max\limits_{x\in C} (-\lambda_j(x))+1.$ Here $\lambda_j$ are linear functions called the basic Lagrange polynomials corresponding to $S$. In his previous papers, the author has investigated these formulae if $C=[0,1]^n$. The present paper is related to the case when $C$ coincides with the unit Euclidean ball $B_n=\{x: \|x\|\leq 1\},$ where $\|x\|=\left(\sum\limits_{i=1}^n x_i^2 \right)^{1/2}.$ We establish various relations for $\xi(B_n;S)$ and $\alpha(B_n;S)$, as well as we give their geometric interpretation.

## Full text

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Source: https://tomesphere.com/paper/1905.01937