Proof

Consider first the nullary (i.e., zero-ary) case. Given a terminal object $\ast$, the unique morphism $id_\ast: \ast \to \ast$ is the zero morphism $0$ in its hom-object. For any object $A$, the zero morphism $0_A: \ast \to A$ must equal any morphism $f: \ast \to A$ on account of $f = f id_\ast = f 0 = 0_A$ where the last equation is by $CMon$-enrichment. Hence $\ast$ is initial. (N.B.: this argument applies more generally to categories enriched in pointed sets, and is self-dual.)

Consider now the case of binary (co-)products. Using zero morphisms, in addition to its canonical projection maps $p_i \colon X_1 \times X_2 \to X_i$, any binary product also admits “injection” maps $X_i \to X_1 \times X_2$, and dually for the coproduct:

Observe some basic compatibility of the $Ab$-enrichment with the product:

First, for $(\alpha_1,\beta_1), (\alpha_2, \beta_2)\colon R \to X_1 \times X_2$ then

(using that the projections $p_1$ and $p_2$ are linear and by the universal property of the product).

Second, $(id,0) \circ p_1$ and $(0,id) \circ p_2$ are two projections on $X_1\times X_2$ whose sum is the identity:

(We may check this, via the Yoneda lemma on generalized elements: for $(\alpha, \beta) \colon R \to X_1\times X_2$ any morphism, then $(id,0)\circ p_1 \circ (\alpha,\beta) = (\alpha,0)$ and $(0,id)\circ p_2\circ (\alpha,\beta) = (0,\beta)$, so the statement follows with equation $(\star)$.)

Now observe that for $f_i \;\colon\; X_i \to Q$ any two morphisms, the sum

gives a morphism of cocones

Moreover, this is unique: suppose $\phi'$ is another morphism filling this diagram, then, by using equation $(\star \star)$, we get

This means that $X_1\times X_2$ satisfies the universal property of a coproduct.

By a dual argument, the binary coproduct $X_1 \sqcup X_2$ is seen to also satisfy the universal property of the binary product. By induction, this implies the statement for all finite (co-)products. (If a particular finite (co-)product exists but binary ones do not, one can adapt the above argument directly to that case.)

Proof

The associativity and commutativity of $+$ follows directly from the corresponding properties of $\oplus$. Bilinearity of composition follows from naturality of the diagonal $\Delta_X$ and codiagonal $\nabla_X$:

Proof

By the proof of prop. , the codiagonal on any object in an additive category is the sum of the two projections:

Therefore (checking on generalized elements, as in the proof of prop. ) for all morphisms $f,g \colon X \to Y$ we have commuting squares of the form