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Let $G$ be a group, and let $V$ be a vector space. A representation of $G$ in $V$ is a group homomorphism $\rho\colon G \to \operatorname{GL}(V)$ from $G$ to the general linear group $\operatorname{GL}(V)$ of invertible linear transformations of $V$ .
Equivalently, a representation of $G$ is a vector space $V$ which is a $G$ -module, that is, a (left) module over the group ring $\mathbb{Z}[G]$ . The equivalence is achieved by assigning to each homomorphism $\rho\colon G \to \operatorname{GL}(V)$ the module structure whose scalar multiplication is defined by $g \cdot v := (\rho(g))(v)$ , and extending linearly. Note that, although technically a group representation is a homomorphism such as $\rho$ , most authors invariably denote a representation using the underlying vector space $V$ , with the homomorphism being understood from context, in much the same way that vector spaces themselves are usually described as sets with the corresponding binary operations being understood from context.
(preserving all notation from above)
A representation is faithful if either of the following equivalent conditions is satisfied:
- $\rho\colon G \to \operatorname{GL}(V)$ is injective,
- $V$ is a faithful left $\mathbb{Z}[G]$ -module.
A subrepresentation of $V$ is a subspace $W$ of $V$ which is a left $\mathbb{Z}[G]$ -submodule of $V$ ; such a subspace is sometimes called a $G$ -invariant subspace of $V$ . Equivalently, a subrepresentation of $V$ is a subspace $W$ of $V$ with the property that $$ (\rho(g))(w) \in W \text{ for all } g \in G \text{ and } w \in W. $$
A representation $V$ is called irreducible if it has no subrepresentations other than itself and the zero module.
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