Dvoretzky's theorem

In mathematics, Dvoretzky's theorem is an important structural theorem about normed vector spaces proved by Aryeh Dvoretzky in the early 1960s,^[1] answering a question of Alexander Grothendieck. In essence, it says that every sufficiently high-dimensional normed vector space will have low-dimensional subspaces that are approximately Euclidean. Equivalently, every high-dimensional bounded symmetric convex set has low-dimensional sections that are approximately ellipsoids.

A new proof found by Vitali Milman in the 1970s^[2] was one of the starting points for the development of asymptotic geometric analysis (also called asymptotic functional analysis or the local theory of Banach spaces).^[3]

For every natural number k ∈ N and every ε > 0 there exists a natural number N(k, ε) ∈ N such that if (X, ‖·‖) is any normed space of dimension N(k, ε), there exists a subspace E ⊂ X of dimension k and a positive definite quadratic form Q on E such that the corresponding Euclidean norm

${\displaystyle |\cdot |=\sqrt{Q(\cdot )}}$

on E satisfies:

${\displaystyle |x|\le \Vert x\Vert \le (1+\epsilon )|x|\text{for every}x\in E.}$

In terms of the multiplicative Banach-Mazur distance d the theorem's conclusion can be formulated as:

${\displaystyle d(E,{\ell }_k^2)\le 1+\epsilon }$

where ${\displaystyle {\ell }_k^2}$ denotes the standard k-dimensional Euclidean space.

Since the unit ball of every normed vector space is a bounded, symmetric, convex set and the unit ball of every Euclidean space is an ellipsoid, the theorem may also be formulated as a statement about ellipsoid sections of convex sets.

In 1971, Vitali Milman gave a new proof of Dvoretzky's theorem, making use of the concentration of measure on the sphere to show that a random k-dimensional subspace satisfies the above inequality with probability very close to 1. The proof gives the sharp dependence on k:

${\displaystyle N(k,\epsilon )\le \exp (C(\epsilon )k)}$

where the constant C(ε) only depends on ε.

We can thus state: for every ε > 0 there exists a constant C(ε) > 0 such that for every normed space (X, ‖·‖) of dimension N, there exists a subspace E ⊂ X of dimension k ≥ C(ε) log N and a Euclidean norm |⋅| on E such that

${\displaystyle |x|\le \Vert x\Vert \le (1+\epsilon )|x|\text{for every}x\in E.}$

More precisely, let S^N − 1 denote the unit sphere with respect to some Euclidean structure Q on X, and let σ be the invariant probability measure on S^N − 1. Then:

• there exists such a subspace E with

${\displaystyle k=\dim E\ge C(\epsilon ){\left(\frac{\underset{S^{N-1}}{\int }\Vert \xi \Vert d\sigma (\xi )}{\underset{\xi \in S^{N-1}}{\max }\Vert \xi \Vert }\right)}^{2}N.}$

• For any X one may choose Q so that the term in the brackets will be at most

${\displaystyle c_1\sqrt{\frac{\log N}{N}}.}$

Here c₁ is a universal constant. For given X and ε, the largest possible k is denoted k_*(X) and called the Dvoretzky dimension of X.

The dependence on ε was studied by Yehoram Gordon,^[4][5] who showed that k_*(X) ≥ c₂ ε² log N. Another proof of this result was given by Gideon Schechtman.^[6]

Noga Alon and Vitali Milman showed that the logarithmic bound on the dimension of the subspace in Dvoretzky's theorem can be significantly improved, if one is willing to accept a subspace that is close either to a Euclidean space or to a Chebyshev space. Specifically, for some constant c, every n-dimensional space has a subspace of dimension k ≥ exp(cTemplate:Radic) that is close either to ℓTemplate:Su or to ℓTemplate:Su.^[7]

Important related results were proved by Tadeusz Figiel, Joram Lindenstrauss and Milman.^[8]

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