Parallelepipeds of maximal facet area and total edge length in ellipsoids, through prescribed boundary points

Abstract

Let \[ EA=\x∈Rn:xA-1x 1\, n2, \] where A is real symmetric positive definite. We study full-dimensional parallelepipeds whose 2n vertices lie on ∂EA. First we show that such parallelepipeds are necessarily centred at the origin and are precisely the images, under A1/2, 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 \[ L(EA)=2ntr A. \] Moreover, the prescribed-vertex problem for L has the same answer in every dimension: for every x0∈∂EA there is an inscribed parallelepiped with vertex x0 and total edge length 2ntr A. The proof uses the Schur--Horn theorem applied to the trace-zero matrix A-tr(A)y0y0, where y0=A-1/2x0. For the total (n-1)-dimensional measure S of the facets we prove \[ S(EA)=2n n-(n-2)/2 A\,tr(A-1). \] For n3 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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