Rayleigh–Ritz method

In mathematics, cellular homology in algebraic topology is a homology theory for CW-complexes. It agrees with singular homology, and can provide an effective means of computing homology modules.

Definition

If X is a CW-complex with n-skeleton X_n, the cellular homology modules are defined as the homology groups of the cellular chain complex

${\displaystyle \cdots \to H_{n+1}(X_{n+1},X_n)\to H_n(X_n,X_{n-1})\to H_{n-1}(X_{n-1},X_{n-2})\to \cdots .}$

[${\displaystyle X_{-1}}$ is the empty set]

The group

${\displaystyle H_n(X_n,X_{n-1})}$

is free, with generators which can be identified with the n-cells of X. Let ${\displaystyle e_n^{\alpha }}$ be an n-cell of X, let ${\displaystyle {\chi }_n^{\alpha }:\partial e_n^{\alpha }\cong S^{n-1}\to X_{n-1}}$ be the attaching map, and consider the composite maps

${\displaystyle {\chi }_n^{\alpha \beta }:S^{n-1}\to X_{n-1}\to X_{n-1}/(X_{n-1}-e_{n-1}^{\beta })\cong S^{n-1}}$

where ${\displaystyle e_{n-1}^{\beta }}$ is an ${\displaystyle (n-1)}$-cell of X and the second map is the quotient map identifying ${\displaystyle (X_{n-1}-e_{n-1}^{\beta })}$ to a point.

The boundary map

${\displaystyle d_n:H_n(X_n,X_{n-1})\to H_{n-1}(X_{n-1},X_{n-2})}$

is then given by the formula

${\displaystyle d_n(e_n^{\alpha })=\sum _{\beta }\mathrm{deg}({\chi }_n^{\alpha \beta })e_{n-1}^{\beta }}$

where ${\displaystyle deg({\chi }_n^{\alpha \beta })}$ is the degree of ${\displaystyle {\chi }_n^{\alpha \beta }}$ and the sum is taken over all ${\displaystyle (n-1)}$-cells of X, considered as generators of ${\displaystyle H_{n-1}(X_{n-1},X_{n-2})}$.

Other properties

One sees from the cellular chain complex that the n-skeleton determines all lower-dimensional homology:

${\displaystyle H_k(X)\cong H_k(X_n)}$

for k < n.

An important consequence of the cellular perspective is that if a CW-complex has no cells in consecutive dimensions, all its homology modules are free. For example, complex projective space CPⁿ has a cell structure with one cell in each even dimension; it follows that for 0 ≤ k ≤ n,

${\displaystyle H_{2k}({\mathbb{ℂ}\mathbb{\mathbb{P}}}^n;\mathbb{\mathbb{Z}})\cong \mathbb{\mathbb{Z}}}$

and

${\displaystyle H_{2k+1}({\mathbb{ℂ}\mathbb{\mathbb{P}}}^n)=0.}$

Generalization

The Atiyah-Hirzebruch spectral sequence is the analogous method of computing the (co)homology of a CW-complex, for an arbitrary extraordinary (co)homology theory.

Euler characteristic

For a cellular complex X, let X_j be its j-th skeleton, and c_j be the number of j-cells, i.e. the rank of the free module H_j(X_j, X_j-1). The Euler characteristic of X is defined by

${\displaystyle \chi (X)={\displaystyle \sum _0^n}(-1{)}^j{c}_j.}$

The Euler characteristic is a homotopy invariant. In fact, in terms of the Betti numbers of X,

${\displaystyle \chi (X)={\displaystyle \sum _0^n}(-1{)}^j\text{rank}{H}_j(X).}$

This can be justified as follows. Consider the long exact sequence of relative homology for the triple (X_n, X_{n - 1} , ∅):

${\displaystyle \cdots \to H_i(X_{n-1},\mathrm{\varnothing })\to H_i(X_n,\mathrm{\varnothing })\to H_i(X_n,X_{n-1})\to \cdots .}$

Chasing exactness through the sequence gives

${\displaystyle {\displaystyle \sum _{i=0}^n}(-1{)}^i\text{rank}{H}_i(X_n,\mathrm{\varnothing })={\displaystyle \sum _{i=0}^n}(-1{)}^i\text{rank}{H}_i(X_n,X_{n-1})+{\displaystyle \sum _{i=0}^n}(-1{)}^i\text{rank}{H}_i(X_{n-1},\mathrm{\varnothing }).}$

The same calculation applies to the triple (X_{n - 1}, X_{n - 2}, ∅), etc. By induction,

${\displaystyle {\displaystyle \sum _{i=0}^n}(-1{)}^i\text{rank}{H}_i(X_n,\mathrm{\varnothing })={\displaystyle \sum _{j=0}^n}{\displaystyle \sum _{i=0}^j}(-1{)}^i\text{rank}{H}_i(X_j,X_{j-1})={\displaystyle \sum _{j=0}^n}(-1{)}^j{c}_j.}$

References

• A. Dold: Lectures on Algebraic Topology, Springer ISBN 3-540-58660-1.

• A. Hatcher: Algebraic Topology, Cambridge University Press ISBN 978-0-521-79540-1. A free electronic version is available on the author's homepage.