Definition:Module Direct Product/General Case

Definition
Let $R$ be a ring.

Let $\left\{ \left\langle M_i,+_i,\circ_i\right\rangle\right\}_{i \in I}$ be a family of $R$-modules.

Let:


 * $M = \displaystyle \prod_{i \mathop \in I} M_i$

be the cartesian product of these modules.

The operation $+$ induced on $M$ by $(+_i)_{i\in I}$ is the operation defined by:
 * $\left\langle{a_i}\right\rangle_{i \mathop \in I} + \left\langle{b_i}\right\rangle_{i \mathop \in I} = \left\langle{a_i +_i b_i}\right\rangle_{i \mathop \in I}$

That is, the additive group of the module $M$ is the direct product of the groups $\left\{ \left(M_i,+_i\right)\right\}_{i \in I}$.

The $R$-action $\circ$ induced on $M$ by $(\circ_i)_{i\in I}$ is the operation defined by:
 * $r \circ \left\langle{m_i}\right\rangle_{i \mathop \in I} = \left\langle{r \circ_i m_i}\right\rangle_{i \mathop \in I}$

In Direct Product of Modules is Module, it is shown that $\left\langle{M, +, \circ}\right\rangle$ is an $R$-module.

The module $\left\langle{M, +, \circ}\right\rangle$ is called the (external) direct product of $\left\{ \left\langle M_i,+_i,\circ_i\right\rangle\right\}_{i \in I}$.