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Main Author: Kania, Tomasz
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.16488
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author Kania, Tomasz
author_facet Kania, Tomasz
contents Let \[ \mathcal{E}_A=\{x\in\mathbb{R}^n:x^{\top}A^{-1}x\le 1\},\qquad n\ge2, \] where $A$ is real symmetric positive definite. We study full-dimensional parallelepipeds whose $2^n$ vertices lie on $\partial\mathcal{E}_A$. First we show that such parallelepipeds are necessarily centred at the origin and are precisely the images, under $A^{1/2}$, of orthotopes inscribed in the Euclidean unit sphere. This reduces the extremal questions to finite-dimensional linear algebra. For the total length $L$ of the one-skeleton we prove \[ L_{\max}(\mathcal{E}_A)=2^n\sqrt{\operatorname{tr} A}. \] Moreover, the prescribed-vertex problem for $L$ has the same answer in every dimension: for every $x_0\in\partial\mathcal{E}_A$ there is an inscribed parallelepiped with vertex $x_0$ and total edge length $2^n\sqrt{\operatorname{tr} A}$. The proof uses the Schur--Horn theorem applied to the trace-zero matrix $A-\operatorname{tr}(A)y_0y_0^{\top}$, where $y_0=A^{-1/2}x_0$. For the total $(n-1)$-dimensional measure $S$ of the facets we prove \[ S_{\max}(\mathcal{E}_A)=2^n n^{-(n-2)/2}\sqrt{\det A}\,\sqrt{\operatorname{tr}(A^{-1})}. \] For $n\ge3$ the maximisers are more rigid: on the sphere they are orthotopes with all edge lengths equal and with a Schur--Horn equal diagonal condition for $A^{-1}$. The prescribed-vertex facet-area problem is therefore equivalent to a restricted Schur--Horn problem with a prescribed barycentric basis. In dimension two this recovers the Connes--Zagier property for ellipses. In dimension three, however, the direct higher-dimensional analogue fails for triaxial ellipsoids at principal-axis vertices; an exact obstruction is given.
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spellingShingle Parallelepipeds of maximal facet area and total edge length in ellipsoids, through prescribed boundary points
Kania, Tomasz
Classical Analysis and ODEs
Primary 52A40, Secondary 52B11, 52A38, 15A42, 15A45
Let \[ \mathcal{E}_A=\{x\in\mathbb{R}^n:x^{\top}A^{-1}x\le 1\},\qquad n\ge2, \] where $A$ is real symmetric positive definite. We study full-dimensional parallelepipeds whose $2^n$ vertices lie on $\partial\mathcal{E}_A$. First we show that such parallelepipeds are necessarily centred at the origin and are precisely the images, under $A^{1/2}$, of orthotopes inscribed in the Euclidean unit sphere. This reduces the extremal questions to finite-dimensional linear algebra. For the total length $L$ of the one-skeleton we prove \[ L_{\max}(\mathcal{E}_A)=2^n\sqrt{\operatorname{tr} A}. \] Moreover, the prescribed-vertex problem for $L$ has the same answer in every dimension: for every $x_0\in\partial\mathcal{E}_A$ there is an inscribed parallelepiped with vertex $x_0$ and total edge length $2^n\sqrt{\operatorname{tr} A}$. The proof uses the Schur--Horn theorem applied to the trace-zero matrix $A-\operatorname{tr}(A)y_0y_0^{\top}$, where $y_0=A^{-1/2}x_0$. For the total $(n-1)$-dimensional measure $S$ of the facets we prove \[ S_{\max}(\mathcal{E}_A)=2^n n^{-(n-2)/2}\sqrt{\det A}\,\sqrt{\operatorname{tr}(A^{-1})}. \] For $n\ge3$ the maximisers are more rigid: on the sphere they are orthotopes with all edge lengths equal and with a Schur--Horn equal diagonal condition for $A^{-1}$. The prescribed-vertex facet-area problem is therefore equivalent to a restricted Schur--Horn problem with a prescribed barycentric basis. In dimension two this recovers the Connes--Zagier property for ellipses. In dimension three, however, the direct higher-dimensional analogue fails for triaxial ellipsoids at principal-axis vertices; an exact obstruction is given.
title Parallelepipeds of maximal facet area and total edge length in ellipsoids, through prescribed boundary points
topic Classical Analysis and ODEs
Primary 52A40, Secondary 52B11, 52A38, 15A42, 15A45
url https://arxiv.org/abs/2510.16488