Simplices rarely contain their circumcenter in high dimensions

Jon Eivind Vatne

Applications of Mathematics (2017)

  • Volume: 62, Issue: 3, page 213-223
  • ISSN: 0862-7940

Abstract

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Acute triangles are defined by having all angles less than π / 2 , and are characterized as the triangles containing their circumcenter in the interior. For simplices of dimension n 3 , acuteness is defined by demanding that all dihedral angles between ( n - 1 ) -dimensional faces are smaller than π / 2 . However, there are, in a practical sense, too few acute simplices in general. This is unfortunate, since the acuteness property provides good qualitative features for finite element methods. The property of acuteness is logically independent of the property of containing the circumcenter when the dimension is greater than two. In this article, we show that the latter property is also quite rare in higher dimensions. In a natural probability measure on the set of n -dimensional simplices, we show that the probability that a uniformly random n -simplex contains its circumcenter is 1 / 2 n .

How to cite

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Vatne, Jon Eivind. "Simplices rarely contain their circumcenter in high dimensions." Applications of Mathematics 62.3 (2017): 213-223. <http://eudml.org/doc/288193>.

@article{Vatne2017,
abstract = {Acute triangles are defined by having all angles less than $\pi /2$, and are characterized as the triangles containing their circumcenter in the interior. For simplices of dimension $n\ge 3$, acuteness is defined by demanding that all dihedral angles between $(n-1)$-dimensional faces are smaller than $\pi /2$. However, there are, in a practical sense, too few acute simplices in general. This is unfortunate, since the acuteness property provides good qualitative features for finite element methods. The property of acuteness is logically independent of the property of containing the circumcenter when the dimension is greater than two. In this article, we show that the latter property is also quite rare in higher dimensions. In a natural probability measure on the set of $n$-dimensional simplices, we show that the probability that a uniformly random $n$-simplex contains its circumcenter is $1/2^n$.},
author = {Vatne, Jon Eivind},
journal = {Applications of Mathematics},
keywords = {simplex; circumcenter; finite element method},
language = {eng},
number = {3},
pages = {213-223},
publisher = {Institute of Mathematics, Academy of Sciences of the Czech Republic},
title = {Simplices rarely contain their circumcenter in high dimensions},
url = {http://eudml.org/doc/288193},
volume = {62},
year = {2017},
}

TY - JOUR
AU - Vatne, Jon Eivind
TI - Simplices rarely contain their circumcenter in high dimensions
JO - Applications of Mathematics
PY - 2017
PB - Institute of Mathematics, Academy of Sciences of the Czech Republic
VL - 62
IS - 3
SP - 213
EP - 223
AB - Acute triangles are defined by having all angles less than $\pi /2$, and are characterized as the triangles containing their circumcenter in the interior. For simplices of dimension $n\ge 3$, acuteness is defined by demanding that all dihedral angles between $(n-1)$-dimensional faces are smaller than $\pi /2$. However, there are, in a practical sense, too few acute simplices in general. This is unfortunate, since the acuteness property provides good qualitative features for finite element methods. The property of acuteness is logically independent of the property of containing the circumcenter when the dimension is greater than two. In this article, we show that the latter property is also quite rare in higher dimensions. In a natural probability measure on the set of $n$-dimensional simplices, we show that the probability that a uniformly random $n$-simplex contains its circumcenter is $1/2^n$.
LA - eng
KW - simplex; circumcenter; finite element method
UR - http://eudml.org/doc/288193
ER -

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