Change of fiber

In algebraic topology, given a fibration p:E→B, the change of fiber is a map between the fibers induced by paths in B.

Since a covering is a fibration, the construction generalizes the corresponding facts in the theory of covering spaces.

Definition

If β is a path in B that starts at, say, b, then we have the homotopy ${\displaystyle h:p^{-1}(b)\times I\to I{\overset {\beta }{\to }}B}$  where the first map is a projection. Since p is a fibration, by the homotopy lifting property, h lifts to a homotopy ${\displaystyle g:p^{-1}(b)\times I\to E}$  with ${\displaystyle g_{0}:p^{-1}(b)\hookrightarrow E}$ . We have:

${\displaystyle g_{1}:p^{-1}(b)\to p^{-1}(\beta (1))}$ .

(There might be an ambiguity and so ${\displaystyle \beta \mapsto g_{1}}$  need not be well-defined.)

Let ${\displaystyle \operatorname {Pc} (B)}$  denote the set of path classes in B. We claim that the construction determines the map:

${\displaystyle \tau :\operatorname {Pc} (B)\to }$  the set of homotopy classes of maps.

Suppose β, β' are in the same path class; thus, there is a homotopy h from β to β'. Let

${\displaystyle K=I\times \{0,1\}\cup \{0\}\times I\subset I^{2}}$ .

Drawing a picture, there is a homeomorphism ${\displaystyle I^{2}\to I^{2}}$  that restricts to a homeomorphism ${\displaystyle K\to I\times \{0\}}$ . Let ${\displaystyle f:p^{-1}(b)\times K\to E}$  be such that ${\displaystyle f(x,s,0)=g(x,s)}$ , ${\displaystyle f(x,s,1)=g'(x,s)}$  and ${\displaystyle f(x,0,t)=x}$ .

Then, by the homotopy lifting property, we can lift the homotopy ${\displaystyle p^{-1}(b)\times I^{2}\to I^{2}{\overset {h}{\to }}B}$  to w such that w restricts to ${\displaystyle f}$ . In particular, we have ${\displaystyle g_{1}\sim g_{1}'}$ , establishing the claim.

It is clear from the construction that the map is a homomorphism: if ${\displaystyle \gamma (1)=\beta (0)}$ ,

${\displaystyle \tau ([c_{b}])=\operatorname {id} ,\,\tau ([\beta ]\cdot [\gamma ])=\tau ([\beta ])\circ \tau ([\gamma ])}$ 

where ${\displaystyle c_{b}}$  is the constant path at b. It follows that ${\displaystyle \tau ([\beta ])}$  has inverse. Hence, we can actually say:

${\displaystyle \tau :\operatorname {Pc} (B)\to }$  the set of homotopy classes of homotopy equivalences.

Also, we have: for each b in B,

${\displaystyle \tau :\pi _{1}(B,b)\to }$  { [ƒ] | homotopy equivalence ${\displaystyle f:p^{-1}(b)\to p^{-1}(b)}$  }

which is a group homomorphism (the right-hand side is clearly a group.) In other words, the fundamental group of B at b acts on the fiber over b, up to homotopy. This fact is a useful substitute for the absence of the structure group.

Consequence

One consequence of the construction is the below:

• The fibers of p over a path-component is homotopy equivalent to each other.

References

• James F. Davis, Paul Kirk, Lecture Notes in Algebraic Topology
• May, J. A Concise Course in Algebraic Topology