Example

A pointed endofunctor on a category $C$ is an endofunctor $F$ together with a natural transformation $1_C \to F$ out of the identity functor. Since the endofunctor category $[C, C]$ may be viewed as a strict monoidal category whose monoidal unit is the identity functor, this is an example of a pointed object in a monoidal category.

Example

A pointed abelian group is an abelian group $A$ equipped with a morphism $\mathbb{Z} \to A$, where $\mathbb{Z}$ is the unit for the tensor product of abelian groups.

Example

A pointed module is a module $M$ equipped with a morphism $R \to M$ from the ground ring $R$, where $R$ is also the unit for the tensor product of modules. Similarly, a pointed vector space is a vector space $V$ equipped with a morphism $F \to V$ from the ground field $F$, where $F$ is also the unit for the tensor product of vector spaces.

Example

A bi-pointed set is a pointed set $S$ equipped with a morphism $\mathbb{B} \to S$ from the boolean domain $\mathbb{B}$, where the smash product is the tensor product and the boolean domain is the tensor unit of the monoidal category of pointed sets.

Example

Under change of base of enrichment, pointed objects in the current sense may be compared to pointed objects in the classical sense. For example, if $V$ is a monoidal category, there is a lax monoidal change of base functor

and a pointing of an object $v$ of $V$ is equivalent to a pointing of its underlying object in the classical sense, $1 \to U(v)$.

Example

If $C$ is a monoidal category, then $C^{op}$ acquires a monoidal category structure as well, and the coslice $I \downarrow C^{op}$ of monoidally pointed objects is equivalent to the slice $C \downarrow I$. This can be important in practice. See for example the discussion at affine space which relates the definition of affine space to the slice $Vect_k/k$, and see even more particularly the discussion of the closed monoidal structure of affine spaces.