Auerbach's lemma

In mathematics, Auerbach's lemma, named after Herman Auerbach, is a theorem in functional analysis which asserts that a certain property of Euclidean spaces holds for general finite-dimensional normed vector spaces.

Statement

Let (V, ||·||) be an n-dimensional normed vector space. Then there exists a basis {e1, ..., en} of V such that

||ei|| = 1 and ||ei|| = 1 for i = 1, ..., n

where {e1, ..., en} is a basis of V* dual to {e1, ..., en}, i. e. ei(ej) = δij.

A basis with this property is called an Auerbach basis.

If V is a Euclidean space (or even infinite-dimensional Hilbert space) then this result is obvious as one may take for {ei} any orthonormal basis of V (the dual basis is then {(ei|·)}).

Geometric formulation

An equivalent statement is the following: any centrally symmetric convex body in has a linear image which contains the unit cross-polytope (the unit ball for the norm) and is contained in the unit cube (the unit ball for the norm).

Corollary

The lemma has a corollary with implications to approximation theory.

Let V be an n-dimensional subspace of a normed vector space (X, ||·||). Then there exists a projection P of X onto V such that ||P|| ≤ n.

Proof

Let {e1, ..., en} be an Auerbach basis of V and {e1, ..., en} corresponding dual basis. By Hahn–Banach theorem each ei extends to f iX* such that

||f i|| = 1.

Now set

P(x) = ∑ f i(x) ei.

It's easy to check that P is indeed a projection onto V and that ||P|| ≤ n (this follows from triangle inequality).

References

This article is issued from Wikipedia - version of the 9/21/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.