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CW complex (Definition)

A Hausdorff topological space $ X$ is said to be a CW complex if it satisfies the following conditions:

  1. There exists a filtration by subspaces
    $\displaystyle {X}^{(-1)}\subseteq{X}^{(0)}\subseteq {X}^{(1)}\subseteq {X}^{(2)}\subseteq\cdots $
    with $ X=\bigcup\limits_{n\ge -1} {X}^{(n)}.$
  2. $ {X}^{(-1)}$ is empty, and, for $ n\ge 0, {X}^{(n)}$ is obtained from $ {X}^{(n-1)}$ by attachment of a collection $ {\left\{e_\iota^n:\:\iota\in I_n\right\}}$ of $ n$-cells.
  3. (“closure-finite”) Every closed cell is contained in a finite union of open cells.
  4. (“weak topology”) $ X$ has the weak topology with respect to the collection of all cells. That is, $ A\subset X$ is closed in $ X$ if and only if the intersection of $ A$ with every closed cell $ e$ is closed in $ e$ with respect to the subspace topology.

The letters `C' and `W' stand for “closure-finite” and “weak topology,” respectively. In particular, this means that one shouldn't look too closely at the initials of J.H.C. Whitehead, who invented CW complexes.

The subspace $ {X}^{(n)}$ is called the $ n$-skeleton of $ X.$ Note that there normally are many possible choices of a filtration by skeleta for a given CW complex. A particular choice of skeleta and attaching maps for the cells is called a CW structure on the space.

Intuitively, $ X$ is a CW complex if it can be constructed, starting from a discrete space, by first attaching one-cells, then two-cells, and so on. Note that the definition above does not allow one to attach $ k$-cells before $ h$-cells if $ k>h.$ While some authors allow this in the definition, it seems to be common usage to restrict CW complexes to the definition given here, and to call a space constructed by cell attachment with unrestricted order of dimensions a cell complex. This is not essential for homotopy purposes, since any cell complex is homotopy equivalent to a CW complex.

CW complexes are a generalization of simplicial complexes, and have some of the same advantages. In particular, they allow inductive reasoning on the basis of skeleta. However, CW complexes are far more flexible than simplicial complexes. For a space $ X$ drawn from “everyday” topological spaces, it is a good bet that it is homotopy equivalent, or even homeomorphic, to a CW complex. This includes, for instance, smooth finite-dimensional manifolds, algebraic varieties, certain smooth infinite-dimensional manifolds (such as Hilbert manifolds), and loop spaces of CW complexes. This makes the category of spaces homotopy equivalent to a CW complex a very popular category for doing homotopy theory.

Remark 1   There is potential for confusion in the way words like “open” and “interior” are used for cell complexes. If $ e^k$ is a closed $ k$-cell in CW complex $ X$ it does not follow that the corresponding open cell $ \smash{\overset{\circ}e}^k$ is an open set of $ X.$ It is, however, an open set of the $ k$-skeleton. Also, while $ \smash{\overset{\circ}e}^k$ is often referred to as the “interior” of $ e^k,$ it is not necessarily the case that it is the interior of $ e^k$ in the sense of pointset topology. In particular, any closed 0-cell is its own corresponding open 0-cell, even though it has empty interior in most cases.



"CW complex" is owned by antonio.
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See Also: simplicial complex, cell attachment, approximation theorem for an arbitrary space, spin networks and spin foams, $CW$ complex of spin networks, generalized Hurewicz fundamental theorem, variable network topology

Other names:  CW-complex
Also defines:  skeleton, skeleta, closure-finite, cell complex, CW structure, CW-structure
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Cross-references: open, topology, interior, open set, potential, theory, category, loop spaces, infinite-dimensional, varieties, algebraic, manifolds, finite-dimensional, smooth, homeomorphic, even, topological spaces, flexible, simplicial complexes, homotopy equivalent, homotopy, dimensions, order, cell attachment, discrete space, structure, attaching maps, subspace topology, intersection, closed, cells, weak topology, open cells, union, finite, contained, closed cell, collection, subspaces, filtration, complex, Hausdorff topological space
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This is version 7 of CW complex, born on 2003-02-07, modified 2003-07-21.
Object id is 3994, canonical name is CWComplex.
Accessed 13651 times total.

Classification:
AMS MSC57-XX (Manifolds and cell complexes)
 55-XX (Algebraic topology)
Pending Errata and Addenda
None.
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Discussion
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"subdivided manifold" by Schneemann on 2007-04-14 17:26:45
In a paper by Erik Brisson, "Representing geometric structures in d dimensions: topology and order", the term "subdivided manifold" is used.

Brisson uses the following 'working definition':

"Subdivided manifolds: Let M be a topological d-manifold,
and C = {c_alpha|c_alpha in I_C} a finite collection of disjoint
open k-cells whose union is M (for 0 <= k <= d, c_alpha
is an open t-cell if it is homeomorphic to the open unit
k-ball). Informally, the pair (M, C) is a subdivided
d-manifold if the boundary of every k-cell c_alpha in C is
non-self-intersecting and is equal to a union of cells in
C of lower dimension."

The concept is quite common in computational geometry, though other authors may use variations of vocabulary and definition details.

How does the concept of subdivided manifolds relate to the cw complex? And how can the above be generalized to a better definition, using only concepts from pure topology?

To be honest, I have some problems with your definition above - it's not really clear what a cell is supposed to be. I would prefer something more explicit about partitions, subsets, homeomorphisms and so on, a definition that is less dependant on other concepts. But maybe that's just the modern way of mathematics... or I missed another concept that is closer to my "subdivided manifold" ?
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