Addition of Linear Transformations

Theorem
Let $\struct {G, +_G}$ and $\struct {H, +_H}$ be abelian groups.

Let $\struct {R, +_R, \times_R}$ be a ring.

Let $\struct {G, +_G, \circ_G}$ and $\struct {H, +_H, \circ_H}$ be $R$-modules.

Let $\map {\LL_R} {G, H}$ be the set of all linear transformations from $G$ to $H$.

Let $\oplus_H$ be defined as pointwise addition on $\map {\LL_R} {G, H}$:
 * $\forall \phi, \psi \in \map {\LL_R} {G, H}: \forall x \in G: \map {\paren {\phi \oplus_H \psi} } x := \map \phi x +_H \map \psi x$

Then $\phi \oplus_H \psi: G \to H$ is a linear transformation.

Poof
From the definition of a module, the group $\struct {H, +_H}$ is abelian.

Hence $\struct {H, +_H}$ is a commutative semigroup.

Therefore we can apply Homomorphism on Induced Structure to Commutative Semigroup to show that $\phi +_H \psi: G \to H$ is a homomorphism.

Let $\lambda \in R, x \in G$.

Then: