In mathematics, and especially differential topology, functional analysis and singularity theory, the Whitney topologies are a countably infinite family of topologies defined on the set of smooth mappings between two smooth manifolds. They are named after the American mathematician Hassler Whitney.
Let M and N be two real, smooth manifolds. Furthermore, let C<sup>âÂÂ</sup>(M,N) denote the space of smooth mappings between M and N. The notation C<sup>âÂÂ</sup> means that the mappings are infinitely differentiable, i.e. partial derivatives of all orders exist and are continuous.
For some integer , let J<sup>k</sup>(M,N) denote the k-jet space of mappings between M and N. The jet space can be endowed with a smooth structure (i.e. a structure as a C<sup>âÂÂ</sup> manifold) which make it into a topological space. This topology is used to define a topology on C<sup>âÂÂ</sup>(M,N).
For a fixed integer consider an open subset and denote by S<sup>k</sup>(U) the following:
The sets S<sup>k</sup>(U) form a basis for the Whitney C<sup>k</sup>-topology on C<sup>âÂÂ</sup>(M,N).
For each choice of , the Whitney C<sup>k</sup>-topology gives a topology for C<sup>âÂÂ</sup>(M,N); in other words the Whitney C<sup>k</sup>-topology tells us which subsets of C<sup>âÂÂ</sup>(M,N) are open sets. Let us denote by W<sup>k</sup> the set of open subsets of C<sup>âÂÂ</sup>(M,N) with respect to the Whitney C<sup>k</sup>-topology. Then the Whitney C<sup>âÂÂ</sup>-topology is defined to be the topology whose basis is given by W, where:
Notice that C<sup>âÂÂ</sup>(M,N) has infinite dimension, whereas J<sup>k</sup>(M,N) has finite dimension. In fact, J<sup>k</sup>(M,N) is a real, finite-dimensional manifold. To see this, let denote the space of polynomials, with real coefficients, in m variables of order at most k and with zero as the constant term. This is a real vector space with dimension
Writing } then, by the standard theory of vector spaces and so is a real, finite-dimensional manifold. Next, define:
Using b to denote the dimension B<sup>k</sup><sub>m,n</sub>, we see that , and so is a real, finite-dimensional manifold.
In fact, if M and N have dimension m and n respectively then:
Given the Whitney C<sup>âÂÂ</sup>-topology, the space C<sup>âÂÂ</sup>(M,N) is a Baire space, i.e. every residual set is dense.