Anderson–Kadec theorem
In mathematics, in the areas of topology and functional analysis, the Anderson–Kadec theorem states[1] that any two infinite-dimensional, separable Banach spaces, or, more generally, Fréchet spaces, are homeomorphic as topological spaces. The theorem was proved by Mikhail Kadec (1966) and Richard Davis Anderson.
Statement
[edit]Every infinite-dimensional, separable Fréchet space is homeomorphic to the Cartesian product of countably many copies of the real line
Preliminaries
[edit]Kadec norm: A norm on a normed linear space is called a Kadec norm with respect to a total subset of the dual space if for each sequence the following condition is satisfied:
- If for and then
Eidelheit theorem: A Fréchet space is either isomorphic to a Banach space, or has a quotient space isomorphic to
Kadec renorming theorem: Every separable Banach space admits a Kadec norm with respect to a countable total subset of The new norm is equivalent to the original norm of The set can be taken to be any weak-star dense countable subset of the unit ball of
Sketch of the proof
[edit]In the argument below denotes an infinite-dimensional separable Fréchet space and the relation of topological equivalence (existence of homeomorphism).
A starting point of the proof of the Anderson–Kadec theorem is Kadec's proof that any infinite-dimensional separable Banach space is homeomorphic to
From Eidelheit theorem, it is enough to consider Fréchet space that are not isomorphic to a Banach space. In that case there they have a quotient that is isomorphic to A result of Bartle-Graves-Michael proves that then for some Fréchet space
On the other hand, is a closed subspace of a countable infinite product of separable Banach spaces of separable Banach spaces. The same result of Bartle-Graves-Michael applied to gives a homeomorphism for some Fréchet space From Kadec's result the countable product of infinite-dimensional separable Banach spaces is homeomorphic to
The proof of Anderson–Kadec theorem consists of the sequence of equivalences
See also
[edit]- Metrizable topological vector space – A topological vector space whose topology can be defined by a metric
Notes
[edit]- ^ Bessaga & Pełczyński 1975, p. 189
References
[edit]- Bessaga, C.; Pełczyński, A. (1975), Selected Topics in Infinite-Dimensional Topology, Monografie Matematyczne, Warszawa: Panstwowe wyd. naukowe.
- Torunczyk, H. (1981), Characterizing Hilbert Space Topology, Fundamenta Mathematicae, pp. 247–262.