User:Julian Nill/Fiber bundle

In algebraic topology, a branch of mathematics, a fiber bundle is a topological space that can be represented locally as a Cartesian product of two topological spaces, together with a mapping that reflects this similarity.

Fiber bundles play an important role in homotopy theory, differential geometry, and differential topology.

History

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The concept of a fiber bundle first appeared in connection with the topology and geometry of manifolds.  Herbert Seifert introduced the terms fiber and fiber space in 1933. 

The first definition of a fiber bundle was given by Hassler Whitney in 1935 under the name sphere space. In the years from 1935 to 1940, fiber bundles became a seperate field of research in mathematics. The work of Whitney, Heinz Hopf, and Eduard Stiefel provided perspectives on the importance of fiber bundles in topology and differential geometry. 

By 1950, the definition of a fiber bundle was clearly noted and the theory on homotopy classification and characteristic classes of fiber bundles was advanced by several mathematicians, including Shiing-Shen Chern, Lev Pontryagin, Stiefel, and Whitney. In the years from 1950 to 1955, Friedrich Hirzebruch was able to prove the Hirzebruch-Riemann-Roch theorem using the characteristic classes of fiber bundles. John Milnor gave a construction of a universal fiber bundle for arbitrary topological groups in 1955. In the early 1960s, Alexander Groethendieck, Michael Atiyah, and Hirzebruch developed a generalized cohomology theory, K-theory, using stability classes of vector bundles. 

Formal definition

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A fiber bundle is a quadrupel   consisting of topological spaces     and   and a continuous surjective mapping   where for every   there exists an open neighbourhood   of   and a homeomorphism   so that the following diagram commutes:

 

Here the mapping   is the natural projection. Such a homeomorphism   is called local trivialization of the bundle and the mapping   is called projection. The space   is called base space of the bundle,   the total space and   the fiber.

The space   is provided with the product topology and   with the subspace topology.

In order to additionally mention the fiber of the bundle, it is common to use the notation   for the fiber bundle. Here the mapping   is the inclusion and   is identified with   the fiber over a point   

Each fiber bundle is a Serre fibration. 

Examples

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Tivial bundle

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Let   and   be the projection onto the first factor, then the total space   is not only locally a product, but also globally. Such a fiber bundle is called a trivial bundle or product bundle. 

Covering

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A fiber bundle with discrete fiber is a covering. Similarly, any covering whose fibers all have the same cardinality is a fiber bundle with discrete fiber. In particular, a covering over a connected base space is a fiber bundle. 

Möbius band

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Möbius band

The Möbius band is an illustrative example of a nontrivial fiber bundle. The base space is the circular line   which runs through the center of the band. The fiber is given by a closed interval, e.g.  

The total space is given by the quotient space   with the equivalence relation   given by   The bundle projection   is given by the mapping, induced by the projection   i.e. an equivalence class   is mapped under the bundle projection onto the equivalence class  , where the equivalence relation on   is given by  

The corresponding trivial bundle   is a cylinder. The Möbius band and the cylinder differ by a twist of the fiber. This twist is only globally visible, locally the Möbius band and the cylinder are identical. 

Klein bottle

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Klein bottle

Another nontrivial fiber bundle is the Klein bottle. The base space and the fiber are given by   and the total space is given by the quotient space   where the equivalence relation   is given by   and   The bundle projection   maps an element   onto   with the equivalence relation   on  

The corresponding trivial bundle   is a torus. This is locally indistinguishable from the Klein bottle. 

Hopf bundle

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The Hopf bundle   has spheres as fiber, total space and base space and is one of the first discovered nontrivial fiber bundles. It is a special case for   of the fiber bundle   over the  -dimensional complex projective space.

Further Hopf bundles, also called generalized Hopf bundles, can be derived by replacing the complex numbers by the real numbers, the quaternions and the octonions:

  • The covering   over the  -dimensional projective space yields for   the real Hopf bundle  
  • The quaternions yield a Hopf bundle given by  
  • The octonions yield a Hopf bundle given by  

Further fiber bundles whose fiber, total space and base space are spheres do not exist. This is a consequence of Adam's theorem which solves H. Hopf's problem on the number of mappings between spheres with Hopf-Invariant 1. 

Cross sections

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The cross section of a fiber bundle   is a continuous mapping   which is right inverse to the projection   For every   is the link of projection and section equal to the identity:   In other words for every   the image of the section lies in the fiber over    

A local section of a fiber bundle is a continuous mapping   where   is an open subset and   holds for all   

Bundle morphism

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A bundle morphism (also called bundle mapping) between two fiber bundles   and   is a mapping, that preserves the bundle structure; in some sense, it is a fiber-preserving mapping. More precisely, a bundle morphism is given by a tupel   of two mappings   and   such that   holds. The situation is illustrated by the following commutative diagram:

 

A fiber over   is mapped under   onto a fiber over   this is given by the relation  

If the base spaces are identical, the bundle morphism is given by   and one speaks of a  -morphism or a bundle morphism over   where   The relation   is given by the following diagram:

 

For every   the condition   holds, which is why   is also called fiber-preserving. 

Coordinate bundle

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For every base space of a fiber bundle there exists an atlas   of charts where   are open subsets and   are the local trivializations of the fiber bundle. Two charts   and   can be compared by using continuous transition functions   The transition functions provide information about which symmetries of the fibers are used in the transition. For a point   the transition function is given by the expression   The following diagram illustrates the situation:

 

In the first line, the first component is given by the identity and the second component is given by the transition function. 

A topological transformation group   of a topological space   relative to a map   is a topological group   such that:

  •   is continuous
  •   where   is the identity of   and
  •   for all   and  

Often one considers more than one such map   and therefore abbreviate   by   

A coordinate bundle is a fiber bundle together with an effective topological transformation group   of   such that the following two conditions hold:

  • For every   and   the homeomorphism   corresponds to the operation of a group element in   and
  • for every   the mapping   with   is continuous.

The mappings   are called coordinate transformations (sometimes called transition functions ) and   is called the structure group of the bundle. The coordinate transformations have the following three properties:

  •   for every   and every  
  •   for every  
  •   for every  

Two coordinate bundles with the same base space and total space, the same fiber, projection and structure group are called equivalent if the atlases   and   for two index sets   and   satisfy the following two conditions:

  • For every   the expression   coincides with the operation of a group element and
  • the coordinate transformations   are continuous.

A  -fiber bundle is an equivalence class of coordinate bundles. Often the  -fiber bundle is defined as maximal coordinate bundle. 

The fiber bundle construction theorem provides conditions under which the existence of a coordinate bundle is guaranteed:

For topological transformation group   of a space   and a system of coordinate transformations of a space   that means a cover   and a set   of continuous mappings with the above three properties for coordinate transformations, there exists a coordinate bundle with base space   fiber   structure group   and coordinate transformations   

Principal bundle

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A principal  -bundle is a fiber bundle   with a fiber   and structure group   acting on the fiber by left translation. The structure group acts freely on the total space by right translation with orbit space   

A open cover   of   is called numerable, if there exists a locally finite partition of unity:

  with   for every  

A principal  -bundle   is called numerable, if there is a numerable cover   of   such that the restricted bundles   are trivial bundles for all   A numerable principal  -bundle is called universal bundle, if for every space   the map   from the set of homotopy classes of maps from   to   to the set of isomorphism classes of principal  -bundles is a bijection. In the case of a universal bundle   the base space is called classifying space of   

Principal bundles play an important role in the classification of bundles. Moreover each  -fiber bundle can be associated with a principal bundle and conversely each principal bundle can be associated with a  -fiber bundle.

Associated principal bundle

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For a given  -fiber bundle a  -principal bundle can be constructed. The existence is given by the fiber bundle construction theorem, where the fiber is represented by   and in addition   acts on itself by left multiplication. The base space and the system of coordinate transformations will be choosen identical to those of the  -fiber bundle. 

Associated G-fiber bundle

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For a given  -principal bundle   and a left  -space   a  -fiber bundle can be constructed:

On the product space   there is a right  -space structure defined by   The  -fiber bundle is given by the mapping   with   and the fiber   

Vector bundle

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A vector bundle of rank   over a field   is a fiber bundle   whose fibers have the structure of a  -dimensional  -vector space and, in addition, any local trivialization   for a   induces a  -linear isomorphism on the individual fibers. This means that the mapping   restricted to a   is an isomorphism and thus   holds. Often one considers real or complex vector bundles where the field   is given by the real numbers   or by the complex numbers  

There is a natural bijection between the isomorphism classes of vector bundles with rank   of paracompact spaces   and the set of homotopy classes of mappings from   into the Grassmann manifold of  -dimensional subspaces in  

  

Examples

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  • The tangent bundle of   with total space   and projection   is a vector bundle with fibers   for every  
  • The canonical vector bundle   with rank   of the Grassmann manifold   is given by the total space   and the projection   

Sphere bundle

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A  -sphere bundle is a fiber bundle   whose fiber is   Often the sphere bundle is given in addition with the orthogonal group   as structure group. 

The sphere bundle is called orientable, if the structure group is the rotation group. 

The cohomology of sphere bundles can be computet using the Gysin sequence.

Cohomology of fiber bundles

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The calculation of the cohomology groups of fiber bundles is much more difficult than the calculation of the homotopy groups. The homotopy groups are given by a long exact sequence, whereas the cohomology groups have a long exact sequence only under certain conditions.

For a trivial bundle, the relation of the cohomology groups is given by the Künneth formula. For arbitrary fiber bundles, tools such as spectral sequences are needed.

The Leray-Hirsch theorem provides sufficient conditions on a fiber bundle so that the structure of the cohomology groups is very similar to that of a trivial bundle.

For  -sphere bundles   which additionally satisfy an orientability hypothesis, a long exact sequence of cohomology groups exists. The sequence is known as the Gysin sequence:

 

Here   is a particular Euler class in   

Examples

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  • The Hopf bundle   does not have the cohomology structure of a trivial bundle, since   holds. 
  • For the fiber bundle   holds:   

References

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  • [1] Seifert, Herbert (1933). Topologie Dreidimensionaler Gefaserter Räume (in German). Vol. 2. Acta Mathematica. pp. 147–238. doi:10.1007/BF02398271.
  • [2] Whitney, Hassler (1935). Sphere-Spaces. Vol. 21. Proceedings of the National Academy of Science of the United States of America. pp. 464–468. doi:10.1073/pnas.21.7.464. PMC 1076627.
  • [3] Steenrod, Norman (1951). The Topology of Fibre Bundles. Princeton NJ: Princeton University Press. ISBN 0-691-08055-0.
  • [4] Husemoller, Dale (1994). Fibre Bundles. Princeton NJ: Springer Verlag. ISBN 978-0-387-94087-8.
  • [5] Hatcher, Allen (2001). Algebraic Topology. NY: Cambridge University Press. ISBN 0-521-79160-X.
  • [6] Laures, Gerd; Szymik, Markus (2014). Grundkurs Topologie (in German) (2 ed.). Berlin / Heidelberg: Springer Spektrum. doi:10.1007/978-3-662-45953-9. ISBN 978-3-662-45952-2.
  • [7] Davis, James F.; Kirk, Paul (1991). Lecture Notes in Algebraic Topology. Bloomington, Indiana.{{cite book}}: CS1 maint: location missing publisher (link)
  • [8] Spanier, Edwin H. (1966). Algebraic Topology. Springer. ISBN 978-0-387-90646-1.