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1Obstruction
Prepare: Stepwise Extension of A Cross Section.
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1Obstruction

Prepare: Stepwise Extension of A Cross Section.

Reference: Basic Algebraic Topology and its Application by Mahima Ranjan Adhikari.

Definition 1.1. A path-connected topological space is said to $n$ -simple if there is point $x_{0} \in X$ such that $π_{1} (X, x_{0})$ acts trivially on $π_{n} * X, x_{0})$ in the sense that each element of $π_{1} (X, x_{0})$ acts on $π_{n} (X, x_{0})$ as the identity.

This subsection considers the problems of constructing a cross section of a fiber bundle. Throughout this subsection it is assumed that for the fiber bundle $ξ : F \subset E \to X$ , the base space $X$ is a finite CW-complex. Suppose that the fiber space $F$ is path-connected and $n$ -simple.

We assume that we have a partially defined cross section $f : X^{n} \to E$ , the problem is to extend it over $X^{n + 1}$ . In such a problem, obstruction may appear. Indeed, if $σ$ is an $(n + 1)$ -cell of $X$ , the cross section $f ∣_{\partial σ}$ might describe a nontrivial element in $π_{n} (F)$ and in this case $f$ will not have a continuous extension over $σ$ . Consider the $ψ_{f} : {(n + 1) -cells σ of X} \to π_{n} (F), σ \mapsto [f ∣_{\partial σ}] .$

As by hypothesis, $F$ is $n$ -simple, and $f ∣_{\partial σ}$ is a topological $n$ -sphere, the function $ψ_{f}$ , is well defined and $ψ_{f}$ sends an $(n + 1)$ -cell $σ$ to an element of $π_{n} (F)$ which is determined by $f ∣_{\partial σ}$ through some random trivialization $ψ ∣_{σ} ≅ σ \times F$ . Then $ψ_{f}$ can be extended by linearity and $ψ_{f}$ can be regarded as a $π_{n} (F)$ -valued cochain, abbreviated $c^{n + 1} (f) \in C^{n + 1} (X; π_{n} (F))$ .

Again for every $(n + 2)$ -cell $σ$ , we have $δ ψ_{f} (σ) = ψ_{f} (\partial σ) = [f ∣_{\partial\partial σ}] = 0$ . This shows that $c^{n + 1} (f)$ is a cocycle. Hence its cohomology class $[c^{n + 1} (f)]$ is an element of $H^{n + 1} (X; π_{n} (F))$ , the element is usually abbreviated $γ^{n + 1} (f)$ .

Remark 1.2. Because $c^{n + 1} (f)$ being the zero indicator that all of these elements of $H^{n + 1} (X; π_{n} (F))$ vanish, it asserts that the given partially cross section can be extended to $X^{n + 1}$ using the homotopy between $f ∣_{\partial σ}$ and the constant map.

If we start with a different partially defined cross section $g$ that agrees with $f ∣_{X^{n - 1}}$ , then the resulting cocycle $c^{n + 1} (g)$ would differ from $c^{n + 1} (f)$ by a coboundary. This asserts that there is a well-defined element of the cohomology group $H^{n + 1} (X; π_{n} (F))$ such that if a partially defined cross section on $X^{n + 1}$ exsits that agrees with the given choice on $X^{n - 1}$ , then the cohomology class $γ^{n + 1} (f)$ must be trivial. Its converse is also true as homotopy section is in the sense $p f \sim 1_{d}$ .

Definition 1.3. Given an $(n + 1)$ -cell $σ$ of $X$ , a function $c (f, σ)$ is defined by the rule $c (f, σ) = ψ_{f} (σ) = [f ∣_{\partial σ}] \in π_{n} (F)$ .

Definition 1.4. The function $ψ_{f}$ of $σ$ given $ψ_{f} (σ) = [f ∣_{\partial σ}] = c (f, σ) \in π_{n} (F)$ is called the obstruction cocycle of $f$ and is sometimes denoted by $c (f)$ .

The above discussion with corresponding notations leads to the following important results.

Theorem 1.5. A cross section over $X^{n}$ can be extended over $X^{n + 1}$ iff $c (f, σ)$ vanishes for each $(n + 1)$ -cell $σ$ of $X$ .

Proof.

Proof. Let

X_{σ}

be a base point of a given

(n + 1)

-cell

σ

of

X

and

F_{σ}

be the fiber over

x_{σ}

. Choose an orientation of

σ

. Consider

σ

the oriented cell and

\partial σ

oriented boundary. If

f

is a cross section

f : X^{n} \to E

, define

c (f, σ) = ψ_{f} (σ) = [f ∣_{\partial σ}] \in π_{n} (F)

. As

F

is

n

-simple, the theorem follows.

$□$

Corollary 1.6. Given a fiber bundle $p : E \to X$ whose fiber $F$ is a path-connected $n$ -simple space, then the element $γ^{n + 1} (f) \in H^{n + 1} (X; π_{n} (F))$ vanishes iff there are cross sections of $p : E \to X$ defined over the $n$ -skeleton of $X$ that extend over the $(n + 1)$ -skeleton.

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Now suppose that the base space $B$ is a CW-complex.

Definition 1.7. We say $B$ is $k$ -connected if $π_{i} (X)$ is triviall for $i \leq k$ .

Steenrod shows that the fiber $V_{k} (F)$ is $(n - k - 1)$ -connected, so it is easy to construct a cross-section of $V_{k} (ξ)$ over the $(n - k)$ -skeleton of $B$ .

There exists a cross-section over the $(n - k + 1)$ -skeleton of $B$ if and only if a certain well defined primary obstruction class in $H^{n - k + 1} (B; π_{n - k} (V_{k} (F)))$ is zero.

Setting $j = n - k + 1$ , we will use the notation $o_{j} (ξ) \in H^{j} (B; π_{j - 1} (V_{n - j + 1} (F)))$ for this primary obstruction class. If $j$ is evern, and less than $n$ , then Steenrod shows that the coefficient group $π_{j - 1} (V_{n - j + 1} (F))$ is cyclic of order $2$ , hence canonically isomorphic to $Z_{2}$ . If $j$ is odd, or $j = n$ , the group $π_{j - 1} (V_{n - j + 1} (F))$ is infinite cyclic. However it is not canonically isomorphic to $Z$ (In general twisted).

In any case, there is certainly a unique non-trivial homomorphism $h$ from $π_{j - 1} (V_{n - j + 1} (F))$ to $Z_{2}$ . Hence we can reduce the coefficients modulo $2$ , obtaining an induced cohomology class $h_{*} o_{j} (ξ) \in H^{j} (B; Z_{2})$ .

Theorem 1.8. This reduction modulo $2$ of the obstruction class $o_{j} (ξ)$ is equal to the Stiefel-Whitney class $w_{j} (ξ)$ .

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1Obstruction

Prepare: Stepwise Extension of A Cross Section.

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