Equilateral dimension

The equilateral dimension has been particularly studied for Lebesgue spaces, finite-dimensional normed vector spaces with the $L^p$ norm

$$\backslash \; \backslash |x\backslash |\_p=\backslash bigl(|x\_1|^p+|x\_2|^p+\backslash cdots+|x\_d|^p\backslash bigr)^\{1/p\}.$$

The equilateral dimension of $L^p$ spaces of dimension $d$ behaves differently depending on the value of $p$:

{{unsolved|mathematics|How many equidistant points exist in spaces with Manhattan distance?}}

• For $p=1$, the $L^p$ norm gives rise to Manhattan distance. In this case, it is possible to find $2d$ equidistant points, the vertices of an axis-aligned cross polytope. The equilateral dimension is known to be exactly $2d$ for $d\backslash le\; 4$,{{harvtxt|Bandelt|Chepoi|Laurent|1998}}; {{harvtxt|Koolen|Laurent|Schrijver|2000}}. and to be upper bounded by $O(d\backslash log\; d)$ for all $d$.{{harvtxt|Alon|Pudlák|2003}}. Robert B. Kusner suggested in 1983 that the equilateral dimension for this case should be exactly $2d$; this suggestion (together with a related suggestion for the equilateral dimension when $p>2$) has come to be known as Kusner's conjecture.
• For
• For $p=2$, the $L^p$ norm is the familiar Euclidean distance. The equilateral dimension of $d$-dimensional Euclidean space is $d+1$: the $d+1$ vertices of an equilateral triangle, regular tetrahedron, or higher-dimensional regular simplex form an equilateral set, and every equilateral set must have this form.{{harvtxt|Guy|1983}}.
• For
• For $p=\backslash infty$ (the limiting case of the $L^p$ norm for finite values of $p$, in the limit as $p$ grows to infinity) the $L^p$ norm becomes the Chebyshev distance, the maximum absolute value of the differences of the coordinates. For a $d$-dimensional vector space with the Chebyshev distance, the equilateral dimension is $2^d$: the $2^d$ vertices of an axis-aligned hypercube are at equal distances from each other, and no larger equilateral set is possible.

Equilateral dimension has also been considered for normed vector spaces with norms other than the $L^p$ norms. The problem of determining the equilateral dimension for a given norm is closely related to the kissing number problem: the kissing number in a normed space is the maximum number of disjoint translates of a unit ball that can all touch a single central ball, whereas the equilateral dimension is the maximum number of disjoint translates that can all touch each other.

For a normed vector space of dimension $d$, the equilateral dimension is at most $2^d$; that is, the $L^\backslash infty$ norm has the highest equilateral dimension among all normed spaces.{{harvtxt|Petty|1971}}. {{harvtxt|Petty|1971}} asked whether every normed vector space of dimension $d$ has equilateral dimension at least $d+1$, but this remains unknown. There exist normed spaces in any dimension for which certain sets of four equilateral points cannot be extended to any larger equilateral set but these spaces may have larger equilateral sets that do not include these four points. For norms that are sufficiently close in Banach–Mazur distance to an $L^p$ norm, Petty's question has a positive answer: the equilateral dimension is at least $d+1$.{{harvtxt|Swanepoel|Villa|2008}}.

It is not possible for high-dimensional spaces to have bounded equilateral dimension: for any integer $k$, all normed vector spaces of sufficiently high dimension have equilateral dimension at least $k$.{{harvtxt|Braß|1999}}; {{harvtxt|Swanepoel|Villa|2008}}. more specifically, according to a variation of Dvoretzky's theorem by {{harvtxt|Alon|Milman|1983}}, every $d$-dimensional normed space has a $k$-dimensional subspace that is close either to a Euclidean space or to a Chebyshev space, where

$$k\backslash ge\backslash exp(c\backslash sqrt\{\backslash log\; d\})$$

for some constant $c$. Because it is close to a Lebesgue space, this subspace and therefore also the whole space contains an equilateral set of at least $k+1$ points. Therefore, the same superlogarithmic dependence on $d$ holds for the lower bound on the equilateral dimension of $d$-dimensional space.

For any $d$-dimensional Riemannian manifold the equilateral dimension is at least $d+1$. For a $d$-dimensional sphere, the equilateral dimension is $d+2$, the same as for a Euclidean space of one higher dimension into which the sphere can be embedded. At the same time as he posed Kusner's conjecture, Kusner asked whether there exist Riemannian metrics with bounded dimension as a manifold but arbitrarily high equilateral dimension.

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Category:Metric geometry

Category:Dimension theory