Fibered manifold

In differential geometry, in the category of differentiable manifolds, a fibered manifold is a surjective submersion $${\displaystyle \pi :E\to B}$$ that is, a surjective differentiable mapping such that at each point ${\displaystyle y\in U}$ the tangent mapping $${\displaystyle T_y\pi :T_{y}E\to T_{\pi (y)}B}$$ is surjective, or, equivalently, its rank equals ${\displaystyle \dim B.}$^[1]

In topology, the words fiber (Faser in German) and fiber space (gefaserter Raum) appeared for the first time in a paper by Herbert Seifert in 1932, but his definitions are limited to a very special case.^[2] 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 ${\displaystyle E}$ was not part of the structure, but derived from it as a quotient space of ${\displaystyle E.}$ The first definition of fiber space is given by Hassler Whitney in 1935 under the name sphere space, but in 1940 Whitney changed the name to sphere bundle.^[3][4]

The theory of fibered spaces, of which vector bundles, principal bundles, topological fibrations and fibered manifolds are a special case, is attributed to Seifert, Hopf, Feldbau, Whitney, Steenrod, Ehresmann, Serre, and others.^{[5][6][7][8][9]}

A triple ${\displaystyle (E,\pi ,B)}$ where ${\displaystyle E}$ and ${\displaystyle B}$ are differentiable manifolds and ${\displaystyle \pi :E\to B}$ is a surjective submersion, is called a fibered manifold.^[10] ${\displaystyle E}$ is called the total space, ${\displaystyle B}$ is called the base.

• Every differentiable fiber bundle is a fibered manifold.
• Every differentiable covering space is a fibered manifold with discrete fiber.
• In general, a fibered manifold need not be a fiber bundle: different fibers may have different topologies. An example of this phenomenon may be constructed by taking the trivial bundle ${\displaystyle (S^1\times \mathbb{ℝ},{\pi }_1,S^1)}$ and deleting two points in two different fibers over the base manifold ${\displaystyle S^1.}$ The result is a new fibered manifold where all the fibers except two are connected.

• Any surjective submersion ${\displaystyle \pi :E\to B}$ is open: for each open ${\displaystyle V\subseteq E,}$ the set ${\displaystyle \pi (V)\subseteq B}$ is open in ${\displaystyle B.}$
• Each fiber ${\displaystyle {\pi }^{-1}(b)\subseteq E,b\in B}$ is a closed embedded submanifold of ${\displaystyle E}$ of dimension ${\displaystyle \dim E-\dim B.}$^[11]
• A fibered manifold admits local sections: For each ${\displaystyle y\in E}$ there is an open neighborhood ${\displaystyle U}$ of ${\displaystyle \pi (y)}$ in ${\displaystyle B}$ and a smooth mapping ${\displaystyle s:U\to E}$ with ${\displaystyle \pi \circ s={\mathrm{Id}}_U}$ and ${\displaystyle s(\pi (y))=y.}$
• A surjection ${\displaystyle \pi :E\to B}$ is a fibered manifold if and only if there exists a local section ${\displaystyle s:B\to E}$ of ${\displaystyle \pi }$ (with ${\displaystyle \pi \circ s={\mathrm{Id}}_B}$) passing through each ${\displaystyle y\in E.}$^[12]

Let ${\displaystyle B}$ (resp. ${\displaystyle E}$) be an ${\displaystyle n}$-dimensional (resp. ${\displaystyle p}$-dimensional) manifold. A fibered manifold ${\displaystyle (E,\pi ,B)}$ admits fiber charts. We say that a chart ${\displaystyle (V,\psi )}$ on ${\displaystyle E}$ is a fiber chart, or is adapted to the surjective submersion ${\displaystyle \pi :E\to B}$ if there exists a chart ${\displaystyle (U,\phi )}$ on ${\displaystyle B}$ such that ${\displaystyle U=\pi (V)}$ and $${\displaystyle u^1=x^1\circ \pi ,u^2=x^2\circ \pi ,\dots ,u^n=x^n\circ \pi ,}$$ where $${\displaystyle \begin{array}{rl}\psi & =(u^1,\dots ,u^n,y^1,\dots ,y^{p-n}).y_0\in V,\\ \phi & =(x^1,\dots ,x^n),\pi \left(y_0\right)\in U.\end{array}}$$

The above fiber chart condition may be equivalently expressed by $${\displaystyle \phi \circ \pi ={\mathrm{p}\mathrm{r}}_1\circ \psi ,}$$ where $${\displaystyle {\mathrm{p}\mathrm{r}}_1}:{\mathbb{ℝ}}^n\times {\mathbb{ℝ}}^{p-n}\to {\mathbb{ℝ}}^n$$ is the projection onto the first ${\displaystyle n}$ coordinates. The chart ${\displaystyle (U,\phi )}$ is then obviously unique. In view of the above property, the fibered coordinates of a fiber chart ${\displaystyle (V,\psi )}$ are usually denoted by ${\displaystyle \psi =(x^i,y^{\sigma })}$ where ${\displaystyle i\in \{1,\dots ,n\},}$ ${\displaystyle \sigma \in \{1,\dots ,m\},}$ ${\displaystyle m=p-n}$ the coordinates of the corresponding chart ${\displaystyle (U,\phi )}$ on ${\displaystyle B}$ are then denoted, with the obvious convention, by ${\displaystyle \phi =\left(x_i\right)}$ where ${\displaystyle i\in \{1,\dots ,n\}.}$

Conversely, if a surjection ${\displaystyle \pi :E\to B}$ admits a fibered atlas, then ${\displaystyle \pi :E\to B}$ is a fibered manifold.

Let ${\displaystyle E\to B}$ be a fibered manifold and ${\displaystyle V}$ any manifold. Then an open covering ${\displaystyle \left\{U_{\alpha }\right\}}$ of ${\displaystyle B}$ together with maps $${\displaystyle \psi :{\pi }^{-1}\left(U_{\alpha }\right)\to U_{\alpha }\times V,}$$ called trivialization maps, such that $${\displaystyle {\mathrm{p}\mathrm{r}}_1\circ {\psi }_{\alpha }=\pi ,\text{ for all }\alpha }$$ is a local trivialization with respect to ${\displaystyle V.}$^[13]

A fibered manifold together with a manifold ${\displaystyle V}$ is a fiber bundle with typical fiber (or just fiber) ${\displaystyle V}$ if it admits a local trivialization with respect to ${\displaystyle V.}$ The atlas ${\displaystyle \mathrm{\Psi }=\left\{(U_{\alpha },{\psi }_{\alpha })\right\}}$ is then called a bundle atlas.

• Connection (fibred manifold) – Operation on fibered manifolds
• Covering space – Type of continuous map in topology
• Fibration – Concept in algebraic topology
• Natural bundle
• Quasi-fibration – Concept from mathematics
• Seifert fiber space – Topological space

• Kolář, Ivan; Michor, Peter; Slovák, Jan (1993), Natural operators in differential geometry, Springer-Verlag, http://www.emis.de/monographs/KSM/kmsbookh.pdf, retrieved 2011-06-15 
• Krupka, Demeter; Janyška, Josef (1990), Lectures on differential invariants, Univerzita J. E. Purkyně V Brně, ISBN 80-210-0165-8 
• Saunders, D.J. (1989), The geometry of jet bundles, Cambridge University Press, ISBN 0-521-36948-7, https://archive.org/details/geometryofjetbun0000saun 
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• Ehresmann, C. (1947a). "Sur la théorie des espaces fibrés" (in French). Coll. Top. Alg. Paris C.N.R.S.: 3–15. 
• Ehresmann, C. (1947b). "Sur les espaces fibrés différentiables" (in French). C. R. Acad. Sci. Paris 224: 1611–1612. 
• Ehresmann, C. (1955). "Les prolongements d'un espace fibré différentiable" (in French). C. R. Acad. Sci. Paris 240: 1755–1757. 
• Feldbau, J. (1939). "Sur la classification des espaces fibrés" (in French). C. R. Acad. Sci. Paris 208: 1621–1623. 
• Seifert, H. (1932). "Topologie dreidimensionaler geschlossener Räume" (in French). Acta Math. 60: 147–238. doi:10.1007/bf02398271. 
• Serre, J.-P. (1951). "Homologie singulière des espaces fibrés. Applications" (in French). Ann. of Math. 54: 425–505. doi:10.2307/1969485. 
• Whitney, H. (1935). "Sphere spaces". Proc. Natl. Acad. Sci. USA 21 (7): 464–468. doi:10.1073/pnas.21.7.464. PMID 16588001. Bibcode: 1935PNAS...21..464W. 
• Whitney, H. (1940). "On the theory of sphere bundles". Proc. Natl. Acad. Sci. USA 26 (2): 148–153. doi:10.1073/pnas.26.2.148. PMID 16588328. Bibcode: 1940PNAS...26..148W. 

• McCleary, J.. "A History of Manifolds and Fibre Spaces: Tortoises and Hares". http://pages.vassar.edu/mccleary/files/2011/04/history.fibre_.spaces.pdf. 

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