Path space fibration

In algebraic topology, the path space fibration over a based space (X, *)^[1] is a fibration of the form

${\displaystyle \Omega X\hookrightarrow PX{\overset {\chi \mapsto \chi (1)}{\to }}X}$

where

• ${\displaystyle PX=\operatorname {Map} (I,X)=\{f:I\to X|f(0)=*\}}$ is the space called the path space of X.
• ${\displaystyle \Omega X}$ is the fiber of ${\displaystyle \chi \mapsto \chi (1)}$ over the base point of X; thus it is the loop space of X.

The space ${\displaystyle X^{I}}$ consists of all maps from I to X that may not preserve the base points; it is called the free path space of X and the fibration ${\displaystyle X^{I}\to X}$ given by, say, ${\displaystyle \chi \mapsto \chi (1)}$, is called the free path space fibration.

The path space fibration can be understood to be dual to the mapping cone^{[disambiguation needed]}. The reduced fibration is called the mapping fiber or, equivalently, the homotopy fiber.

If ƒ:X→Y is any map, then the mapping path space P_ƒ of ƒ is the pullback of ${\displaystyle Y^{I}\to Y,\,\chi \mapsto \chi (1)}$ along ƒ. Since a fibration pullbacks to a fibration, if Y is based, one has the fibration

${\displaystyle F_{f}\hookrightarrow P_{f}{\overset {p}{\to }}Y}$

where ${\displaystyle p(x,\chi )=\chi (0)}$ and ${\displaystyle F_{f}}$ is the homotopy fiber, the pullback of ${\displaystyle PY{\overset {\chi \mapsto \chi (1)}{\to }}Y}$ along ƒ.

Note also ƒ is the composition

${\displaystyle X{\overset {\phi }{\to }}P_{f}{\overset {p}{\to }}Y}$

where the first map φ sends x to ${\displaystyle (x,c_{f(x)})}$, ${\displaystyle c_{f(x)}}$ the constant path with value ƒ(x). Clearly, φ is a homotopy equivalence; thus, the above decomposition says that any map is a fibration up to homotopy equivalence.

If ƒ is a fibration to begin with, then ${\displaystyle \phi :X\to P_{f}}$ is a fiber-homotopy equivalence and, consequently,^[2] the fibers of f over the path-component of the base point are homotopy equivalent to the homotopy fiber ${\displaystyle F_{f}}$ of ƒ.

By definition, a path in a space X is a map from the unit interval I to X. Again by definition, the product of two paths α, β such that α(1) = β(0) is the path β · α: I → X given by:

${\displaystyle (\beta \cdot \alpha )(t)={\begin{cases}\alpha (2t)&{\text{if }}0\leq t\leq 1/2\\\beta (2t-1)&{\text{if }}1/2\leq t\leq 1\\\end{cases}}}$.

This product, in general, fails to be associative on the nose: (γ · β) · α ≠ γ · (β · α), as seen directly. One solution to this failure is to pass to homotopy classes: one has [(γ · β) · α ] = [γ · (β · α)]. Another solution is to work with paths of arbitrary length, leading to the notions of Moore's path space and Moore's path space fibration.^[3]

Given a based space (X, *), we let

${\displaystyle P'X=\{f:[0,r]\to X|r\geq 0,f(0)=*\}.}$

An element f of this set has the unique extension ${\displaystyle {\widetilde {f}}}$ to the interval ${\displaystyle [0,\infty )}$ such that ${\displaystyle {\widetilde {f}}(t)=f(r),\,t\geq r}$. Thus, the set can be identified as a subspace of ${\displaystyle \operatorname {Map} ([0,\infty ),X)}$. The resulting space is called Moore's path space of X. Then, just as before, there is a fibration, Moore's path space fibration:

${\displaystyle \Omega 'X\hookrightarrow P'X{\overset {p}{\to }}X}$

where p sends each f: [0, r] → X to f(r) and ${\displaystyle \Omega 'X=p^{-1}(*)}$ is the fiber. It turns out that ${\displaystyle \Omega X}$ and ${\displaystyle \Omega 'X}$ are homotopy equivalent.

Now, we define the product map:

${\displaystyle \mu :P'X\times \Omega 'X\to P'X}$

by: for ${\displaystyle f:[0,r]\to X}$ and ${\displaystyle g:[0,s]\to X}$,

${\displaystyle \mu (g,f)(t)={\begin{cases}f(t)&{\text{if }}0\leq t\leq r\\g(t-r)&{\text{if }}r\leq t\leq s+r\\\end{cases}}}$.

This product is manifestly associative. In particular, with μ restricted to Ω'X × Ω'X, we have that Ω'X is a topological monoid (in the category of all spaces). Moreover, this monoid Ω'X acts on P'X through the original μ. In fact, ${\displaystyle p:P'X\to X}$ is an Ω'X-fibration.^[4]

• James F. Davis, Paul Kirk, Lecture Notes in Algebraic Topology
• May, J. A Concise Course in Algebraic Topology
• George William Whitehead (1978). Elements of homotopy theory. Graduate Texts in Mathematics. Vol. 61 (3rd ed.). New York-Berlin: Springer-Verlag. pp. xxi+744. ISBN 978-0-387-90336-1. MR 0516508. Retrieved September 6, 2011.