Banach–Stone theorem


In mathematics, the Banach–Stone theorem is a classical result in the theory of continuous functions on topological spaces, named after the mathematicians Stefan Banach and Marshall Stone.
In brief, the Banach–Stone theorem allows one to recover a compact Hausdorff space from the algebra of scalars. In modern language, this is the commutative case of the spectrum of a C*-algebra, and the Banach–Stone theorem can be seen as a functional analysis analog of the connection between a ring R and the spectrum of a ring Spec in algebraic geometry.

Statement

For a topological space X, let Cb denote the normed vector space of continuous, real-valued, bounded functions f : XR equipped with the supremum norm ‖·‖. This is an algebra, called the algebra of scalars, under pointwise multiplication of functions. For a compact space X, Cb is the same as C, the space of all continuous functions f : XR. The algebra of scalars is a functional analysis analog of the ring of regular functions in algebraic geometry, there denoted.
Let X and Y be compact, Hausdorff spaces and let T : CC be a surjective linear isometry. Then there exists a homeomorphism φ : YX and gC with
and
The case where X and Y are compact metric spaces is due to Banach, while the extension to compact Hausdorff spaces is due to Stone. In fact, they both prove a slight generalization—they do not assume that T is linear, only that it is an isometry in the sense of metric spaces, and use the Mazur–Ulam theorem to show that T is affine, and so is a linear isometry.

Generalizations

The Banach–Stone theorem has some generalizations for vector-valued continuous functions on compact, Hausdorff topological spaces. For example, if E is a Banach space with trivial centralizer and X and Y are compact, then every linear isometry of C onto C is a strong Banach–Stone map.
More significantly, the Banach–Stone theorem suggests the philosophy that one can replace a space by an algebra, with no loss. Reversing this, it suggests that one can consider algebraic objects, even if they do not come from a geometric object, as a kind of "algebra of scalars". In this vein, any commutative C*-algebra is the algebra of scalars on a Hausdorff space. Thus one may consider noncommutative C*-algebras as non-commutative spaces. This is the basis of the field of noncommutative geometry.