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In [[mathematics]], the '''Leray–Hirsch theorem'''<ref>A. Hatcher, ''Algebraic Topology'', Cambridge University Press, http://www.math.cornell.edu/~hatcher/AT/AT.pdf</ref> is a basic result on the [[algebraic topology]] of [[fiber bundle]]s. It is named after [[Jean Leray]] and [[Guy Hirsch]], who independently proved it in the late 1940s. It can be thought of as a mild generalization of the [[Künneth formula]], which computes the cohomology of a product space as a tensor product of the cohomologies of the direct factors. It is a very special case of the [[Leray spectral sequence]]. | |||
==Statement== | |||
===Setup=== | |||
Let <math>\pi:E\longrightarrow B</math> | |||
be a [[fibre bundle]] with fibre ''F''. Assume that for each degree <math>p</math>, the [[singular cohomology]] rational [[vector space]] | |||
:<math>H^p(F) = H^p(F; \mathbb{Q})</math> | |||
is finite dimensional, and that the inclusion | |||
:<math>\iota: F \longrightarrow E</math> | |||
induces a ''surjection'' in rational cohomology | |||
:<math>\iota^* : H^* (E) \longrightarrow H^* (F)</math>. | |||
Consider a ''section'' of this surjection | |||
:<math> s: H^* (F) \longrightarrow H^* (E)</math>, | |||
by definition, this map satisfies | |||
:<math>\iota^* \circ s = \mathrm {Id}</math>. | |||
===The Leray-Hirsch isomorphism=== | |||
The Leray–Hirsch theorem states that the linear map | |||
:<math>\begin{array}{ccc} | |||
H^* (F)\otimes H^*(B) & \longrightarrow & H^* (E) \\ | |||
\alpha \otimes \beta & \longmapsto & s (\alpha)\cup \pi^*(\beta) | |||
\end{array}</math> | |||
is an isomorphism of ''H*(B)''-modules. | |||
===Statement in coordinates=== | |||
In other words, if for every <math>p</math>, there exist classes | |||
:<math>c_{1,p},\ldots,c_{m_p,p} \in H^p(E)</math> | |||
that restrict, on each fiber ''F'', to a basis of the cohomology in degree <math>p</math>, the map given below is then an [[isomorphism]] of <math>H^*(B)</math> [[Module (mathematics)|module]]s. | |||
:<math>\begin{array}{ccc} | |||
H^*(F)\otimes H^*(B) & \longrightarrow & H^*(E) \\ | |||
\sum_{i,j,k}a_{i,j,k}\iota^*(c_{i,j})\otimes b_k & \longmapsto & \sum_{i,j,k}a_{i,j,k}c_{i,j}\wedge\pi^*(b_k) | |||
\end{array}</math> | |||
where <math>\{b_k\}</math> is a basis for <math>H^*(B)</math> and thus, induces a basis <math>\{\iota^*(c_{i,j})\otimes b_k\}</math> for <math>H^*(F)\otimes H^*(B).</math> | |||
==Notes== | |||
<references/> | |||
{{DEFAULTSORT:Leray-Hirsch theorem}} | |||
[[Category:Fiber bundles]] | |||
[[Category:Theorems in algebraic topology]] | |||
{{topology-stub}} | |||
Latest revision as of 09:06, 2 March 2013
In mathematics, the Leray–Hirsch theorem[1] is a basic result on the algebraic topology of fiber bundles. It is named after Jean Leray and Guy Hirsch, who independently proved it in the late 1940s. It can be thought of as a mild generalization of the Künneth formula, which computes the cohomology of a product space as a tensor product of the cohomologies of the direct factors. It is a very special case of the Leray spectral sequence.
Statement
Setup
Let be a fibre bundle with fibre F. Assume that for each degree , the singular cohomology rational vector space
is finite dimensional, and that the inclusion
induces a surjection in rational cohomology
- .
Consider a section of this surjection
- ,
by definition, this map satisfies
- .
The Leray-Hirsch isomorphism
The Leray–Hirsch theorem states that the linear map
is an isomorphism of H*(B)-modules.
Statement in coordinates
In other words, if for every , there exist classes
that restrict, on each fiber F, to a basis of the cohomology in degree , the map given below is then an isomorphism of modules.
where is a basis for and thus, induces a basis for
Notes
- ↑ A. Hatcher, Algebraic Topology, Cambridge University Press, http://www.math.cornell.edu/~hatcher/AT/AT.pdf