In differential geometry, the integration along fibers of a k-form yields a -form where m is the dimension of the fiber, via "integration". It is also called the fiber integration.
Let be a fiber bundle over a manifold with compact oriented fibers. If is a k-form on E, then for tangent vectors wi's at b, let
where is the induced top-form on the fiber ; i.e., an -form given by: with lifts of to ,
(To see is smooth, work it out in coordinates; cf. an example below.)
Then is a linear map . By Stokes' formula, if the fibers have no boundaries(i.e. ), the map descends to de Rham cohomology:
This is also called the fiber integration.
Now, suppose is a sphere bundle; i.e., the typical fiber is a sphere. Then there is an exact sequence, K the kernel,
which leads to a long exact sequence, dropping the coefficient and using :
From this local calculation, the next formula follows easily (see Poincaré_lemma#Direct_proof): if is any k-form on
where is the restriction of to .
As an application of this formula, let be a smooth map (thought of as a homotopy). Then the composition is a homotopy operator (also called a chain homotopy):
which implies induce the same map on cohomology, the fact known as the homotopy invariance of de Rham cohomology. As a corollary, for example, let U be an open ball in Rn with center at the origin and let . Then , the fact known as the Poincaré lemma.
Given a vector bundle π : E → B over a manifold, we say a differential form α on E has vertical-compact support if the restriction has compact support for each b in B. We write for the vector space of differential forms on E with vertical-compact support.
If E is oriented as a vector bundle, exactly as before, we can define the integration along the fiber:
The following is known as the projection formula.[2] We make a right -module by setting .
Proposition — Let be an oriented vector bundle over a manifold and the integration along the fiber. Then
is -linear; i.e., for any form β on B and any form α on E with vertical-compact support,
If B is oriented as a manifold, then for any form α on E with vertical compact support and any form β on B with compact support,
.
Proof: 1. Since the assertion is local, we can assume π is trivial: i.e., is a projection. Let be the coordinates on the fiber. If , then, since is a ring homomorphism,
Similarly, both sides are zero if α does not contain dt. The proof of 2. is similar.