In mathematics, specifically Homological algebra, a double complex is a generalization of a chain complex where instead of having a
Z
Z x Z
l{A}
Cp,q\inOb(l{A})
and the vertical differentialdh:Cp,q\toCp+1,q
which have the compatibility relation
v:C d p,q \toCp,q+1
Hence a double complex is a commutative diagram of the formdh\circdv=dv\circdh
where the rows and columns form chain complexes.\begin{matrix} &&\vdots&&\vdots&&\\ &&\uparrow&&\uparrow&&\\ … &\to&Cp,q+1&\to&Cp+1,q+1&\to& … \\ &&\uparrow&&\uparrow&&\\ … &\to&Cp,q&\to&Cp+1,q&\to& … \\ &&\uparrow&&\uparrow&&\\ &&\vdots&&\vdots&&\\ \end{matrix}
Some authors[2] instead require that the squares anticommute. That is
dh\circdv+dv\circdh=0.
This eases the definition of Total Complexes. By setting
fp,q=(-1)p
| v | |
| d | |
| p,q |
\colonCp,q\toCp,q-1
There are many natural examples of bicomplexes that come up in nature. In particular, for a Lie groupoid, there is a bicomplex associated to it[3] pg 7-8 which can be used to construct its de-Rham complex.
X
\Omegap,q(X)
z1,z2
C2
\overline{z}1,\overline{z}2
(1,1)
fa,bdza\wedged\overline{z}b