Generalized coordinates: Difference between revisions

In mathematics, especially in the field of category theory, the concept of injective object is a generalization of the concept of injective module. This concept is important in homotopy theory and in theory of model categories. The dual notion is that of a projective object.

General Definition

Let ${\displaystyle \mathfrak{C}}$ be a category and let ${\displaystyle \mathcal{\mathscr{H}}}$ be a class of morphisms of ${\displaystyle \mathfrak{C}}$.

An object ${\displaystyle Q}$ of ${\displaystyle \mathfrak{C}}$ is said to be ${\displaystyle \mathcal{\mathscr{H}}}$-injective if for every morphism ${\displaystyle f:A\to Q}$ and every morphism ${\displaystyle h:A\to B}$ in ${\displaystyle \mathcal{\mathscr{H}}}$ there exists a morphism ${\displaystyle g:B\to Q}$ extending (the domain of) ${\displaystyle f}$, i.e ${\displaystyle gh=f}$. In other words, ${\displaystyle Q}$ is injective iff any ${\displaystyle \mathcal{\mathscr{H}}}$-morphism into ${\displaystyle Q}$ extends (via composition on the left) to a morphism into ${\displaystyle Q}$.

The morphism ${\displaystyle g}$ in the above definition is not required to be uniquely determined by ${\displaystyle h}$ and ${\displaystyle f}$.

In a locally small category, it is equivalent to require that the hom functor ${\displaystyle Ho{m}_{\mathfrak{C}}(-,Q)}$ carries ${\displaystyle \mathcal{\mathscr{H}}}$-morphisms to epimorphisms (surjections).

The classical choice for ${\displaystyle \mathcal{\mathscr{H}}}$ is the class of monomorphisms, in this case, the expression injective object is used.

Abelian case

If ${\displaystyle \mathfrak{C}}$ is an abelian category, an object A of ${\displaystyle \mathfrak{C}}$ is injective iff its hom functor Hom_C(–,A) is exact.

The abelian case was the original framework for the notion of injectivity.

Enough injectives

Let ${\displaystyle \mathfrak{C}}$ be a category, H a class of morphisms of ${\displaystyle \mathfrak{C}}$ ; the category ${\displaystyle \mathfrak{C}}$ is said to have enough H-injectives if for every object X of ${\displaystyle \mathfrak{C}}$, there exist a H-morphism from X to an H-injective object.

Injective hull

A H-morphism g in ${\displaystyle \mathfrak{C}}$ is called H-essential if for any morphism f, the composite fg is in H only if f is in H.

If f is a H-essential H-morphism with a domain X and an H-injective codomain G, G is called an H-injective hull of X. This H-injective hull is then unique up to a canonical isomorphism.

Examples

• In the category of Abelian groups and group homomorphisms, an injective object is a divisible group.
• In the category of modules and module homomorphisms, R-Mod, an injective object is an injective module. R-Mod has injective hulls (as a consequence, R-Mod has enough injectives).
• In the category of metric spaces and nonexpansive mappings, Met, an injective object is an injective metric space, and the injective hull of a metric space is its tight span.
• In the category of T0 spaces and continuous mappings, an injective object is always a Scott topology on a continuous lattice therefore it is always sober and locally compact.
• In the category of simplicial sets, the injective objects with respect to the class of anodyne extensions are Kan complexes.
• In the category of partially ordered sets and monotonic functions between posets, the complete lattices form the injective objects for order-embeddings, and the Dedekind–MacNeille completion of a partially ordered set is its injective hull.
• One also talks about injective objects in more general categories, for instance in functor categories or in categories of sheaves of O_X modules over some ringed space (X,O_X).

References

• J. Rosicky, Injectivity and accessible categories
• F. Cagliari and S. Montovani, T₀-reflection and injective hulls of fibre spaces

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