Path space fibration

In algebraic topology, the path space fibration over a pointed space ${\displaystyle (X,*)}$^[1] is a fibration of the form^[2]

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

where

• ${\displaystyle PX}$ is the based path space of the pointed space ${\displaystyle (X,*)}$; that is, $$\begin{gathered} {\displaystyle PX=\{f:I\to X\mid f \\ \text{continuous},f(0)=*\}} \end{gathered}$$ equipped with the compact-open topology.
• ${\displaystyle \mathrm{\Omega }X}$ is the fiber of ${\displaystyle \chi \mapsto \chi (1)}$ over the base point of ${\displaystyle (X,*)}$; thus it is the loop space of ${\displaystyle (X,*)}$.

The free path space of X, that is, ${\displaystyle \mathrm{Map}(I,X)=X^I}$, consists of all maps from I to X that do not necessarily begin at a base point, 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.^{[clarification needed]} The fiber of the based fibration is called the mapping fiber or, equivalently, the homotopy fiber.

Mapping path space

If ${\displaystyle f:X\to Y}$ is any map, then the mapping path space ${\displaystyle P_f}$ of ${\displaystyle f}$ is the pullback of the fibration ${\displaystyle Y^I\to Y,\chi \mapsto \chi (1)}$ along ${\displaystyle f}$. (A mapping path space satisfies the universal property that is dual to that of a mapping cylinder, which is a push-out. Because of this, a mapping path space is also called a mapping cocylinder.^[3]) Since a fibration pulls back to a fibration, if Y is based, one has the fibration

${\displaystyle F_f\hookrightarrow P_f\stackrel{p}{\to }Y}$

where ${\displaystyle p(x,\chi )=\chi (0)}$ and ${\displaystyle F_f}$ is the homotopy fiber, the pullback of the fibration ${\displaystyle PY\stackrel{\chi \mapsto \chi (1)}{⟶}Y}$ along ${\displaystyle f}$. Note also ${\displaystyle f}$ is the composition

${\displaystyle X\stackrel{\varphi }{\to }{P}_f\stackrel{p}{\to }Y}$

where the first map ${\displaystyle \varphi }$ sends x to ${\displaystyle (x,c_{f(x)})}$; here ${\displaystyle c_{f(x)}}$ denotes the constant path with value ${\displaystyle f(x)}$. Clearly, ${\displaystyle \varphi }$ is a homotopy equivalence; thus, the above decomposition says that any map is a fibration up to homotopy equivalence. If ${\displaystyle f}$ is a fibration to begin with, then the map ${\displaystyle \varphi :X\to P_f}$ is a fiber-homotopy equivalence and, consequently,^[4] the fibers of ${\displaystyle f}$ over the path-component of the base point are homotopy equivalent to the homotopy fiber ${\displaystyle F_f}$ of ${\displaystyle f}$.

Moore's path space

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 ${\displaystyle \alpha ,\beta }$ such that ${\displaystyle \alpha (1)=\beta (0)}$ is the path ${\displaystyle \beta \cdot \alpha :I\to X}$ given by:

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

This product, in general, fails to be associative on the nose: ${\displaystyle (\gamma \cdot \beta )\cdot \alpha \ne \gamma \cdot (\beta \cdot \alpha )}$, as seen directly. One solution to this failure is to pass to homotopy classes: one has ${\displaystyle [(\gamma \cdot \beta )\cdot \alpha ]=[\gamma \cdot (\beta \cdot \alpha )]}$. Another solution is to work with paths of arbitrary lengths, leading to the notions of Moore's path space and Moore's path space fibration, described below.^[5] (A more sophisticated solution is to rethink composition: work with an arbitrary family of compositions; see the introduction of Lurie's paper,^[6] leading to the notion of an operad.) Given a based space ${\displaystyle (X,*)}$, we let

${\displaystyle P^{\prime }X=\{f:[0,r]\to X\mid r\ge 0,f(0)=*\}.}$

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

${\displaystyle {\mathrm{\Omega }}^{\prime }X\hookrightarrow P^{\prime }X\stackrel{p}{\to }X}$

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

${\displaystyle \mu :P^{\prime }X\times {\mathrm{\Omega }}^{\prime }X\to P^{\prime }X}$

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

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

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, ${\displaystyle p:P^{\prime }X\to X}$ is an Ω'X-fibration.^[7]

Notes

References

• Davis, James F.; Kirk, Paul (2001). Lecture Notes in Algebraic Topology (PDF). Graduate Studies in Mathematics. Vol. 35. Providence, RI: American Mathematical Society. pp. xvi+367. doi:10.1090/gsm/035. ISBN 0-8218-2160-1. MR 1841974.
• May, J. Peter (1999). A Concise Course in Algebraic Topology (PDF). Chicago Lectures in Mathematics. Chicago, IL: University of Chicago Press. pp. x+243. ISBN 0-226-51182-0. MR 1702278.
• Whitehead, George W. (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.