In topology, the terms fiber (German: Faser) and fiber space (gefaserter Raum) appeared for the first time in a paper by Herbert Seifert in 1933,^[1][2][3] but his definitions are limited to a very special case. The main difference from the present day conception of a fiber space, however, was that for Seifert what is now called the base space (topological space) of a fiber (topological) space E was not part of the structure, but derived from it as a quotient space of E. The first definition of fiber space was given by Hassler Whitney in 1935^[4] under the name sphere space, but in 1940 Whitney changed the name to sphere bundle.^[5]

The theory of fibered spaces, of which vector bundles, principal bundles, topological fibrations and fibered manifolds are a special case, is attributed to Seifert, Heinz Hopf, Jacques Feldbau,^[6] Whitney, Norman Steenrod, Charles Ehresmann,^[7][8][9] Jean-Pierre Serre,^[10] and others.

Fiber bundles became their own object of study in the period 1935–1940. The first general definition appeared in the works of Whitney.^[11]

Whitney came to the general definition of a fiber bundle from his study of a more particular notion of a sphere bundle,^[12] that is a fiber bundle whose fiber is a sphere of arbitrary dimension.^[13]

A fiber bundle is a structure ${\displaystyle (E,\,B,\,\pi ,\,F),}$  where ${\displaystyle E,B,}$  and ${\displaystyle F}$  are topological spaces and ${\displaystyle \pi :E\to B}$  is a continuous surjection satisfying a local triviality condition outlined below. The space ${\displaystyle B}$  is called the base space of the bundle, ${\displaystyle E}$  the total space, and ${\displaystyle F}$  the fiber. The map ${\displaystyle \pi }$  is called the projection map (or bundle projection). We shall assume in what follows that the base space ${\displaystyle B}$  is connected.

We require that for every ${\displaystyle x\in B}$ , there is an open neighborhood ${\displaystyle U\subseteq B}$  of ${\displaystyle x}$  (which will be called a trivializing neighborhood) such that there is a homeomorphism ${\displaystyle \varphi :\pi ^{-1}(U)\to U\times F}$  (where ${\displaystyle \pi ^{-1}(U)}$  is given the subspace topology, and ${\displaystyle U\times F}$  is the product space) in such a way that ${\displaystyle \pi }$  agrees with the projection onto the first factor. That is, the following diagram should commute:

where ${\displaystyle \operatorname {proj} _{1}:U\times F\to U}$  is the natural projection and ${\displaystyle \varphi :\pi ^{-1}(U)\to U\times F}$  is a homeomorphism. The set of all ${\displaystyle \left\{\left(U_{i},\,\varphi _{i}\right)\right\}}$  is called a local trivialization of the bundle.

Thus for any ${\displaystyle p\in B}$ , the preimage ${\displaystyle \pi ^{-1}(\{p\})}$  is homeomorphic to ${\displaystyle F}$  (since this is true of ${\displaystyle \operatorname {proj} _{1}^{-1}(\{p\})}$ ) and is called the fiber over ${\displaystyle p.}$  Every fiber bundle ${\displaystyle \pi :E\to B}$  is an open map, since projections of products are open maps. Therefore ${\displaystyle B}$  carries the quotient topology determined by the map ${\displaystyle \pi .}$ 

A fiber bundle ${\displaystyle (E,\,B,\,\pi ,\,F)}$  is often denoted

${\displaystyle {\begin{matrix}{}\\F\longrightarrow E\ {\xrightarrow {\,\ \pi \ }}\ B\\{}\end{matrix}}}$

(1)

that, in analogy with a short exact sequence, indicates which space is the fiber, total space and base space, as well as the map from total to base space.

A smooth fiber bundle is a fiber bundle in the category of smooth manifolds. That is, ${\displaystyle E,B,}$  and ${\displaystyle F}$  are required to be smooth manifolds and all the functions above are required to be smooth maps.

Trivial bundle Edit

Let ${\displaystyle E=B\times F}$  and let ${\displaystyle \pi :E\to B}$  be the projection onto the first factor. Then ${\displaystyle \pi }$  is a fiber bundle (of ${\displaystyle F}$ ) over ${\displaystyle B.}$  Here ${\displaystyle E}$  is not just locally a product but globally one. Any such fiber bundle is called a trivial bundle. Any fiber bundle over a contractible CW-complex is trivial.

Nontrivial bundles Edit

Möbius strip Edit

Perhaps the simplest example of a nontrivial bundle ${\displaystyle E}$  is the Möbius strip. It has the circle that runs lengthwise along the center of the strip as a base ${\displaystyle B}$  and a line segment for the fiber ${\displaystyle F}$ , so the Möbius strip is a bundle of the line segment over the circle. A neighborhood ${\displaystyle U}$  of ${\displaystyle \pi (x)\in B}$  (where ${\displaystyle x\in E}$ ) is an arc; in the picture, this is the length of one of the squares. The preimage ${\displaystyle \pi ^{-1}(U)}$  in the picture is a (somewhat twisted) slice of the strip four squares wide and one long (i.e. all the points that project to ${\displaystyle U}$ ).

A homeomorphism (${\displaystyle \varphi }$  in § Formal definition) exists that maps the preimage of ${\displaystyle U}$  (the trivializing neighborhood) to a slice of a cylinder: curved, but not twisted. This pair locally trivializes the strip. The corresponding trivial bundle ${\displaystyle B\times F}$  would be a cylinder, but the Möbius strip has an overall "twist". This twist is visible only globally; locally the Möbius strip and the cylinder are identical (making a single vertical cut in either gives the same space).

Klein bottle Edit

A similar nontrivial bundle is the Klein bottle, which can be viewed as a "twisted" circle bundle over another circle. The corresponding non-twisted (trivial) bundle is the 2-torus, ${\displaystyle S^{1}\times S^{1}}$ .

Covering map Edit

A covering space is a fiber bundle such that the bundle projection is a local homeomorphism. It follows that the fiber is a discrete space.

Vector and principal bundles Edit

A special class of fiber bundles, called vector bundles, are those whose fibers are vector spaces (to qualify as a vector bundle the structure group of the bundle — see below — must be a linear group). Important examples of vector bundles include the tangent bundle and cotangent bundle of a smooth manifold. From any vector bundle, one can construct the frame bundle of bases, which is a principal bundle (see below).

Another special class of fiber bundles, called principal bundles, are bundles on whose fibers a free and transitive action by a group ${\displaystyle G}$  is given, so that each fiber is a principal homogeneous space. The bundle is often specified along with the group by referring to it as a principal ${\displaystyle G}$ -bundle. The group ${\displaystyle G}$  is also the structure group of the bundle. Given a representation ${\displaystyle \rho }$  of ${\displaystyle G}$  on a vector space ${\displaystyle V}$ , a vector bundle with ${\displaystyle \rho (G)\subseteq {\text{Aut}}(V)}$  as a structure group may be constructed, known as the associated bundle.

Sphere bundles Edit

A sphere bundle is a fiber bundle whose fiber is an n-sphere. Given a vector bundle ${\displaystyle E}$  with a metric (such as the tangent bundle to a Riemannian manifold) one can construct the associated unit sphere bundle, for which the fiber over a point ${\displaystyle x}$  is the set of all unit vectors in ${\displaystyle E_{x}}$ . When the vector bundle in question is the tangent bundle ${\displaystyle TM}$ , the unit sphere bundle is known as the unit tangent bundle.

A sphere bundle is partially characterized by its Euler class, which is a degree ${\displaystyle n+1}$  cohomology class in the total space of the bundle. In the case ${\displaystyle n=1}$  the sphere bundle is called a circle bundle and the Euler class is equal to the first Chern class, which characterizes the topology of the bundle completely. For any ${\displaystyle n}$ , given the Euler class of a bundle, one can calculate its cohomology using a long exact sequence called the Gysin sequence.

Mapping tori Edit

If ${\displaystyle X}$  is a topological space and ${\displaystyle f:X\to X}$  is a homeomorphism then the mapping torus ${\displaystyle M_{f}}$  has a natural structure of a fiber bundle over the circle with fiber ${\displaystyle X.}$  Mapping tori of homeomorphisms of surfaces are of particular importance in 3-manifold topology.

Quotient spaces Edit

If ${\displaystyle G}$  is a topological group and ${\displaystyle H}$  is a closed subgroup, then under some circumstances, the quotient space ${\displaystyle G/H}$  together with the quotient map ${\displaystyle \pi :G\to G/H}$  is a fiber bundle, whose fiber is the topological space ${\displaystyle H}$ . A necessary and sufficient condition for (${\displaystyle G,\,G/H,\,\pi ,\,H}$ ) to form a fiber bundle is that the mapping ${\displaystyle \pi }$  admits local cross-sections (Steenrod 1951, §7).

The most general conditions under which the quotient map will admit local cross-sections are not known, although if ${\displaystyle G}$  is a Lie group and ${\displaystyle H}$  a closed subgroup (and thus a Lie subgroup by Cartan's theorem), then the quotient map is a fiber bundle. One example of this is the Hopf fibration, ${\displaystyle S^{3}\to S^{2}}$ , which is a fiber bundle over the sphere ${\displaystyle S^{2}}$  whose total space is ${\displaystyle S^{3}}$ . From the perspective of Lie groups, ${\displaystyle S^{3}}$  can be identified with the special unitary group ${\displaystyle SU(2)}$ . The abelian subgroup of diagonal matrices is isomorphic to the circle group ${\displaystyle U(1)}$ , and the quotient ${\displaystyle SU(2)/U(1)}$  is diffeomorphic to the sphere.

More generally, if ${\displaystyle G}$  is any topological group and ${\displaystyle H}$  a closed subgroup that also happens to be a Lie group, then ${\displaystyle G\to G/H}$  is a fiber bundle.

A section (or cross section) of a fiber bundle ${\displaystyle \pi }$  is a continuous map ${\displaystyle f:B\to E}$  such that ${\displaystyle \pi (f(x))=x}$  for all x in B. Since bundles do not in general have globally defined sections, one of the purposes of the theory is to account for their existence. The obstruction to the existence of a section can often be measured by a cohomology class, which leads to the theory of characteristic classes in algebraic topology.

The most well-known example is the hairy ball theorem, where the Euler class is the obstruction to the tangent bundle of the 2-sphere having a nowhere vanishing section.

Often one would like to define sections only locally (especially when global sections do not exist). A local section of a fiber bundle is a continuous map ${\displaystyle f:U\to E}$  where U is an open set in B and ${\displaystyle \pi (f(x))=x}$  for all x in U. If ${\displaystyle (U,\,\varphi )}$  is a local trivialization chart then local sections always exist over U. Such sections are in 1-1 correspondence with continuous maps ${\displaystyle U\to F}$ . Sections form a sheaf.

Fiber bundles often come with a group of symmetries that describe the matching conditions between overlapping local trivialization charts. Specifically, let G be a topological group that acts continuously on the fiber space F on the left. We lose nothing if we require G to act faithfully on F so that it may be thought of as a group of homeomorphisms of F. A G-atlas for the bundle ${\displaystyle (E,B,\pi ,F)}$  is a set of local trivialization charts ${\displaystyle \{(U_{k},\,\varphi _{k})\}}$  such that for any ${\displaystyle \varphi _{i},\varphi _{j}}$  for the overlapping charts ${\displaystyle (U_{i},\,\varphi _{i})}$  and ${\displaystyle (U_{j},\,\varphi _{j})}$  the function

In the smooth category, a G-bundle is a smooth fiber bundle where G is a Lie group and the corresponding action on F is smooth and the transition functions are all smooth maps.

The transition functions ${\displaystyle t_{ij}}$  satisfy the following conditions

1. ${\displaystyle t_{ii}(x)=1\,}$ 
2. ${\displaystyle t_{ij}(x)=t_{ji}(x)^{-1}\,}$ 
3. ${\displaystyle t_{ik}(x)=t_{ij}(x)t_{jk}(x).\,}$ 

The third condition applies on triple overlaps U_i ∩ U_j ∩ U_k and is called the cocycle condition (see Čech cohomology). The importance of this is that the transition functions determine the fiber bundle (if one assumes the Čech cocycle condition).

A principal G-bundle is a G-bundle where the fiber F is a principal homogeneous space for the left action of G itself (equivalently, one can specify that the action of G on the fiber F is free and transitive, i.e. regular). In this case, it is often a matter of convenience to identify F with G and so obtain a (right) action of G on the principal bundle.

It is useful to have notions of a mapping between two fiber bundles. Suppose that M and N are base spaces, and ${\displaystyle \pi _{E}:E\to M}$  and ${\displaystyle \pi _{F}:F\to N}$  are fiber bundles over M and N, respectively. A bundle map or bundle morphism consists of a pair of continuous^[14] functions

For fiber bundles with structure group G and whose total spaces are (right) G-spaces (such as a principal bundle), bundle morphisms are also required to be G-equivariant on the fibers. This means that ${\displaystyle \varphi :E\to F}$  is also G-morphism from one G-space to another, that is, ${\displaystyle \varphi (xs)=\varphi (x)s}$  for all ${\displaystyle x\in E}$  and ${\displaystyle s\in G.}$ 

In case the base spaces M and N coincide, then a bundle morphism over M from the fiber bundle ${\displaystyle \pi _{E}:E\to M}$  to ${\displaystyle \pi _{F}:F\to M}$  is a map ${\displaystyle \varphi :E\to F}$  such that ${\displaystyle \pi _{E}=\pi _{F}\circ \varphi .}$  This means that the bundle map ${\displaystyle \varphi :E\to F}$  covers the identity of M. That is, ${\displaystyle f\equiv \mathrm {id} _{M}}$  and the following diagram commutes:

Assume that both ${\displaystyle \pi _{E}:E\to M}$  and ${\displaystyle \pi _{F}:F\to M}$  are defined over the same base space M. A bundle isomorphism is a bundle map ${\displaystyle (\varphi ,\,f)}$  between ${\displaystyle \pi _{E}:E\to M}$  and ${\displaystyle \pi _{F}:F\to M}$  such that ${\displaystyle f\equiv \mathrm {id} _{M}}$  and such that ${\displaystyle \varphi }$  is also a homeomorphism.^[15]

In the category of differentiable manifolds, fiber bundles arise naturally as submersions of one manifold to another. Not every (differentiable) submersion ${\displaystyle f:M\to N}$  from a differentiable manifold M to another differentiable manifold N gives rise to a differentiable fiber bundle. For one thing, the map must be surjective, and ${\displaystyle (M,N,f)}$  is called a fibered manifold. However, this necessary condition is not quite sufficient, and there are a variety of sufficient conditions in common use.

If M and N are compact and connected, then any submersion ${\displaystyle f:M\to N}$  gives rise to a fiber bundle in the sense that there is a fiber space F diffeomorphic to each of the fibers such that ${\displaystyle (E,B,\pi ,F)=(M,N,f,F)}$  is a fiber bundle. (Surjectivity of ${\displaystyle f}$  follows by the assumptions already given in this case.) More generally, the assumption of compactness can be relaxed if the submersion ${\displaystyle f:M\to N}$  is assumed to be a surjective proper map, meaning that ${\displaystyle f^{-1}(K)}$  is compact for every compact subset K of N. Another sufficient condition, due to Ehresmann (1951), is that if ${\displaystyle f:M\to N}$  is a surjective submersion with M and N differentiable manifolds such that the preimage ${\displaystyle f^{-1}\{x\}}$  is compact and connected for all ${\displaystyle x\in N,}$  then ${\displaystyle f}$  admits a compatible fiber bundle structure (Michor 2008, §17).

• The notion of a bundle applies to many more categories in mathematics, at the expense of appropriately modifying the local triviality condition; cf. principal homogeneous space and torsor (algebraic geometry).
• In topology, a fibration is a mapping ${\displaystyle \pi :E\to B}$  that has certain homotopy-theoretic properties in common with fiber bundles. Specifically, under mild technical assumptions a fiber bundle always has the homotopy lifting property or homotopy covering property (see Steenrod (1951, 11.7) for details). This is the defining property of a fibration.
• A section of a fiber bundle is a "function whose output range is continuously dependent on the input." This property is formally captured in the notion of dependent type.

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• Steenrod, Norman (April 5, 1999). The Topology of Fibre Bundles. Princeton Mathematical Series. Vol. 14. Princeton, N.J.: Princeton University Press. ISBN 978-0-691-00548-5. OCLC 40734875.
• Bleecker, David (1981), Gauge Theory and Variational Principles, Reading, Mass: Addison-Wesley publishing, ISBN 978-0-201-10096-9
• Ehresmann, Charles (1951). "Les connexions infinitésimales dans un espace fibré différentiable". Colloque de Topologie (Espaces fibrés), Bruxelles, 1950. Paris: Georges Thone, Liège; Masson et Cie. pp. 29–55.
• Husemoller, Dale (1994), Fibre Bundles, Springer Verlag, ISBN 978-0-387-94087-8
• Michor, Peter W. (2008), Topics in Differential Geometry, Graduate Studies in Mathematics, vol. 93, Providence: American Mathematical Society, ISBN 978-0-8218-2003-2
• Voitsekhovskii, M.I. (2001) [1994], "Fibre space", Encyclopedia of Mathematics, EMS Press

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