In s.

There is an evident difference between one-dimensional real line bundles (as just described) and one-dimensional .

A real line bundle is therefore in the eyes of or the real line: the data are equivalent.

In the case of the complex line bundle, we are looking in fact also for circle bundles. There are some celebrated ones, for example the Hopf fibrations of spheres to spheres.

=Determinant bundles=

In general if V is a vector bundle on a space X , with constant fibre dimension n , the n -th exterior power of V taken fibre-by-fibre is a line bundle, called the determinant line bundle. This construction is in particular applied to the tangent bundle of a smooth manifold. The resulting determinant bundle is responsible for the phenomenon of tensor density, in the sense that for an orientable manifold it has a global section, and its tensor powers with any real exponent may be defined and used to twist any vector bundle by tensor product.

=Universal bundles and classifying spaces=

From the point of view still of homotopy theory there are universal bundles for real line bundles (respectively, complex line bundles). According to general theory about classifying spaces, we should look for contractible spaces on which there are group actions of the respective groups C 2 and S 1, that are free actions. Those spaces can serve as the universal principal bundles, and the quotients for the actions as the classifying spaces BG . In these cases we can find those explicitly, in the infinite-dimensional analogues of real and complex projective space.

Therefore the classifying space BC 2 is of the homotopy type of RP∞, the real projective space given by an infinite sequence of homogeneous coordinates. It carries the universal real line bundle; in terms of homotopy theory that means that any real line bundle L on a CW complex X determines a classifying map from X to RP∞, making L a bundle isomorphic to the pullback of the universal bundle. This classifying map can be used to define the Stiefel-Whitney class of L , in the first cohomology of X with Z/2Z coefficients, from a standard class on RP∞.

In an analogous way, the complex projective space CP carries a universal complex line bundle. In this case classifying maps give rise to the first Chern class of X , in H2( X ) (integral cohomology).

There is a further, analogous theory with quaternionic (real dimension four) line bundles. This gives rise to one of the Pontryagin classes, in real four-dimensional cohomology.

In this way foundational cases for the theory of characteristic classes depend only on line bundles. According to a general splitting principle this can determine the rest of the theory (if not explicitly).

There are theories of holomorphic line bundles on complex manifolds, and invertible sheaf in algebraic geometry, that work out a line bundle theory in those areas.

=References=