Definition:Homomorphism of Complexes

Definition
Let $\left({R, +, \cdot}\right)$ be a ring.

Let:
 * $M: \quad \cdots \longrightarrow M_i \stackrel {d_i} {\longrightarrow} M_{i + 1} \stackrel {d_{i + 1} } {\longrightarrow} M_{i + 2} \stackrel {d_{i + 2} } {\longrightarrow} \cdots$

and
 * $N: \quad \cdots \longrightarrow N_i \stackrel {d'_i} {\longrightarrow} N_{i + 1} \stackrel {d'_{i + 1} } {\longrightarrow} N_{i + 2} \stackrel {d'_{i + 2} } {\longrightarrow} \cdots$

be two differential complexes of $R$-modules.

Let $\phi = \left\{ {\phi_i: i \in \Z}\right\}$ be a family of module homomorphisms $\phi_i: M_i \to N_i$.

Then $\phi$ is a homomorphism of complexes for each $i \in \Z$:
 * $\phi_{i+1} \circ d_i = \phi_i \circ d'_i$

That is, for each $i \in \Z$ we have a commutative diagram:


 * $\begin{xy}\xymatrix@L+2mu@+1em {

M_i \ar[r]^*{d_i} \ar[d]^*{\phi_i} & M_{i+1} \ar[d]^*{\phi_{i+1}} \\ N_i \ar[r]^*{d'_i} & N_{i+1} } \end{xy}$