In mathematics, a Hilbert manifold is a manifold modeled on Hilbert spaces. Thus it is a separableHausdorff space in which each point has a neighbourhood homeomorphic to an infinite dimensional Hilbert space. The concept of a Hilbert manifold provides a possibility of extending the theory of manifolds to infinite-dimensional setting. Analogous to the finite-dimensional situation, one can define a differentiable Hilbert manifold by considering a maximal atlas in which the transition maps are differentiable.
Properties
Many basic constructions of manifold theory, such as the tangent space of a manifold and a tubular neighbourhood of a submanifold (of finite codimension) carry over from the finite dimensional situation to the Hilbert setting with little change. However, in statements involving maps between manifolds, one often has to restrict consideration to Fredholm maps, that is, maps whose differential at every point is Fredholm. The reason for this is that Sard's lemma holds for Fredholm maps, but not in general. Notwithstanding this difference, Hilbert manifolds have several very nice properties.
Every smooth Hilbert manifold can be smoothly embedded onto an open subset of the model Hilbert space.
Every homotopy equivalence between two Hilbert manifolds is homotopic to a diffeomorphism. In particular every two homotopy equivalent Hilbert manifolds are already diffeomorphic. This stands in contrast to lens spaces and exotic spheres, which demonstrate that in the finite-dimensional situation, homotopy equivalence, homeomorphism, and diffeomorphism of manifolds are distinct properties.
Although Sard's Theorem does not hold in general, every continuous map from a Hilbert manifold can be arbitrary closely approximated by a smooth map which has no critical points.
Examples
Any Hilbert space is a Hilbert manifold with a single global chart given by the identity function on Moreover, since is a vector space, the tangent space to at any point is canonically isomorphic to itself, and so has a natural inner product, the "same" as the one on Thus can be given the structure of a Riemannian manifold with metric where denotes the inner product in
Similarly, any open subset of a Hilbert space is a Hilbert manifold and a Riemannian manifold under the same construction as for the whole space.
There are several mapping spaces between manifolds which can be viewed as Hilbert spaces by only considering maps of suitable Sobolev class. For example we can consider the space of all maps from the unit circle into a manifold This can be topologized via the compact open topology as a subspace of the space of all continuous mappings from the circle to that is, the free loop space of The Sobolev kind mapping space described above is homotopy equivalent to the free loop space. This makes it suited to the study of algebraic topology of the free loop space, especially in the field of string topology. We can do an analogous Sobolev construction for the loop space, making it a codimension Hilbert submanifold of where is the dimension of
Fréchet manifold – topological space modeled on a Fréchet space in much the same way as a manifold is modeled on a Euclidean spacePages displaying wikidata descriptions as a fallback
Global analysis – which uses Hilbert manifolds and other kinds of infinite-dimensional manifolds
References
Klingenberg, Wilhelm (1982), Riemannian Geometry, Berlin: W. de Gruyter, ISBN978-3-11-008673-7. Contains a general introduction to Hilbert manifolds and many details about the free loop space.
Lang, Serge (1995), Differential and Riemannian Manifolds, New York: Springer, ISBN978-0387943381. Another introduction with more differential topology.
N. Kuiper, The homotopy type of the unitary group of Hilbert spaces", Topology 3, 19-30
J. Eells, K. D. Elworthy, "On the differential topology of Hilbert manifolds", Global analysis. Proceedings of Symposia in Pure Mathematics, Volume XV 1970, 41-44.
J. Eells, K. D. Elworthy, "Open embeddings of certain Banach manifolds", Annals of Mathematics 91 (1970), 465-485