Hyperplanes of finite-dimensional normed spaces with the maximal relative projection constant

Abstract

The relative projection constant λ(Y, X) of normed spaces Y ⊂ X is defined as λ(Y, X) = ∈f \ ||P|| : P ∈ P(X, Y) \, where P(X, Y) denotes the set of all continuous projections from X onto Y. By the well-known result of Bohnenblust for every n-dimensional normed space X and its subspace Y of codimension 1 the inequality λ(Y, X) ≤ 2 - 2n holds. The main goal of the paper is to study the equality case in the theorem of Bohnenblust. We establish an equivalent condition for the equality λ(Y, X) = 2 - 2n and present several applications. We prove that every three-dimensional space has a subspace with the projection constant less than 43 - 0.0007. This gives a non-trivial upper bound in the problem posed by Bosznay and Garay. In the general case, we give an upper bound for the number of (n-1)-dimensional subspaces with the maximal relative projection constant in terms of the facets of the unit ball of X. As a consequence, every n-dimensional normed space X has an (n-1)-dimensional subspace Y with λ(Y, X) < 2-2n. This contrasts with the seperable case in which it is possible that every hyperplane has a maximal possible projection constant.