CW-complex

Inductive definition

A CW-complex is a topological space $X$ constructed inductively as follows. We start with the $-1$ -skeleton, which is empty. The $n$ -skeleton, denoted $X^{n}$ , is constructed from the $(n-1)$ -skeleton $X^{n-1}$ , by attaching a discretely parametrized family of attaching maps from $S^{n-1}$ to $X^{n-1}$ , and taking the pushout with respect to these, for the inclusion of $S^{n-1}$ in $D^{n}$ .

The space $X$ is given the union topology for the ascending unions of the skeleta. Each $n$ -skeleton is closed in $X$ , but not necessarily open in $X$ .

A somewhat more general notion than a CW-complex is a cell complex, where we again attach cells, but it is now possible to attach the cells in any order rather than in the order of increasing dimension.

Definition (assuming Hausdorffness)

A CW-complex is the following data, subject to the following conditions.

Data

An ordered triple $(X,E,\Phi )$ where:

$X$ is a Hausdorff space
$E$ is a set of cells in $X$
$\Phi$ is a family of maps parametrized by the members of $E$

Conditions

$X$ is the disjoint union of all cells in $E$
For each $k$ -cell $e\in E$ , the map $(D^{k},S^{k-1})\to (e\cup X^{k-1},X^{k-1})$ is a relative homeomorphism
The closure of any cell in $E$ is contained in a finite union of cells in $E$
$X$ has the weak topology determined by the closures of the cells in $E$

Terminology

$X$ is termed a CW-space
$(E,\Phi )$ is called a CW-decomposition of $X$
$\Phi _{e}$ is termed the characteristic map of $e$