Fibered manifold

In topology, the words fiber (Faser in German) and fiber space (gefaserter Raum) appeared for the first time in a paper by 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 E was not part of the structure, but derived from it as a quotient space of 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 (E, π, B) where E and B are differentiable manifolds and π: E → B is a surjective submersion, is called a fibered manifold.[10] E is called the total space, 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 needs not to be a fiber bundle: different fibers may have different topologies. An example of this phenomenon may be constructed by taking the trivial bundle (S¹ × ℝ, π₁, S¹) and deleting two points in two different fibers over the base manifold S¹.The result is a new fibered manifold where all the fibers except two are connected.

• Any surjective submersion π: E → B is open: for each open V ⊂ E, the set π(V) ⊂ B is open in B.
• Each fiber π⁻¹(b) ⊂ E, b ∈ B is a closed embedded submanifold of E of dimension dim E − dim B.[11]
• A fibered manifold admits local sections: For each y ∈ E there is an open neighborhood U of π(y) in B and a smooth mapping s: U → E with π ∘ s = Id_U and s(π(y)) = y.
• A surjection π : E → B is a fibered manifold if and only if there exists a local section s : B → E of π (with π ∘ s = Id_B) passing through each y ∈ E.[12]

Let B (resp. E) be an n-dimensional (resp. p-dimensional) manifold. A fibered manifold (E, π, B) admits fiber charts. We say that a chart (V, ψ) on E is a fiber chart, or is adapted to the surjective submersion π: E → B if there exists a chart (U, φ) on B such that U = π(V) and

${\displaystyle u^{1}=x^{1}\circ \pi ,\,u^{2}=x^{2}\circ \pi ,\,\dots ,\,u^{n}=x^{n}\circ \pi \,,}$

where

${\displaystyle {\begin{aligned}\psi &=(u^{1},\dots ,u^{n},y^{1},\dots ,y^{p-n}).\quad y_{0}\in V,\\\varphi &=(x^{1},\dots ,x^{n}),\quad \pi (y_{0})\in U.\end{aligned}}}$

The above fiber chart condition may be equivalently expressed by

${\displaystyle \varphi \circ \pi =\mathrm {pr} _{1}\circ \psi ,}$

where

${\displaystyle {\mathrm {pr} _{1}}\colon {\mathbb {R} ^{n}}\times {\mathbb {R} ^{p-n}}\to {\mathbb {R} ^{n}}\,}$

is the projection onto the first n coordinates. The chart (U, φ) is then obviously unique. In view of the above property, the fibered coordinates of a fiber chart (V, ψ) are usually denoted by ψ = (xⁱ, y^σ) where i ∈ {1, ..., n}, σ ∈ {1, ..., m}, m = p − n the coordinates of the corresponding chart U, φ) on B are then denoted, with the obvious convention, by φ = (xⁱ) where i ∈ {1, ..., n}.

Conversely, if a surjection π: E → B admits a fibered atlas, then π: E → B is a fibered manifold.

Let E → B be a fibered manifold and V any manifold. Then an open covering {U_α} of B together with maps

${\displaystyle \psi$ :\pi ^{-1}(U_{\alpha })\rightarrow U_{\alpha }\times V,}

called trivialization maps, such that

${\displaystyle \mathrm {pr} _{1}\circ \psi _{\alpha }=\pi ,\forall \alpha }$

is a local trivialization with respect to V.[13]

A fibered manifold together with a manifold V is a fiber bundle with typical fiber (or just fiber) V if it admits a local trivialization with respect to V. The atlas Ψ = {(U_α, ψ_α)} is then called a bundle atlas.

• Covering space
• Fiber bundle
• Fibration
• Quasi-fibration
• Natural bundle
• Seifert fiber space
• Connection (fibred manifold)
• Algebraic fiber space

• Kolář, Ivan; Michor, Peter; Slovák, Jan (1993), Natural operators in differential geometry (PDF), Springer-Verlag, archived from the original (PDF) on 2017-03-30, 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
• Giachetta, G.; Mangiarotti, L.; Sardanashvily, G. (1997). New Lagrangian and Hamiltonian Methods in Field Theory. World Scientific. ISBN 981-02-1587-8.CS1 maint: ref=harv (link)

• McCleary, J. "A History of Manifolds and Fibre Spaces: Tortoises and Hares" (pdf).