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Idea

An ind-object of a category $C$ is a formal filtered colimit of objects of $C$. The category of ind-objects of $C$ is written $\mathrm{ind}$-$C$.

Here, “ind” is short for “inductive system”, as in the inductive systems used to define directed colimits, and as contrasted with “pro” in the dual notion of pro-object corresponding to “projective system”.

Recalling the nature of filtered colimits, this means that in particular chains of inclusions

of objects in $C$ are regarded to converge to an object in $\mathrm{ind}C$, even if that object does not exist in $C$ itself. Standard examples where ind-objects are relevant are categories $C$ whose objects are finite in some sense, such as finite sets or finite vector spaces. Their ind-categories contain then also the infinite versions of these objects as limits of sequences of inclusions of finite objects of ever increasing size.

Moreover, ind-categories allow one to handle “big things in terms of small things” also in another important sense: many large categories are actually (equivalent to) ind-categories of small categories. This means that, while large, they are for all practical purposes controlled by a small category (see the description of the hom-set of $\mathrm{ind}-C$ in terms of that of $C$ below). Such large categories equivalent to ind-categories are therefore called accessible categories.

Definition

There are several equivalent ways to define ind-objects.

As diagrams

One definition is to define the objects of $\mathrm{ind}$-$C$ to be diagrams $F:D\to C$ where $D$ is a small filtered category.
The idea is to think of these diagrams as being the placeholder for the colimit over them (possibly non-existent in $C$) We identify an ordinary object of $C$ with the corresponding diagram $1\to C$. To see what the morphisms should be between $F:D\to C$ and $G:E\to C$, we stipulate that

1. The embedding $C\to \mathrm{ind}$-$C$ should be full and faithful,
2. each diagram $F:D\to C$ should be the colimit of itself (considered as a diagram in $\mathrm{ind}$-$C$ via the above embedding), and
3. the objects of $C$ should be compact in $\mathrm{ind}$-$C$.

Thus, we should have

Here

• the first step is by assumption that each object is a suitable colimit;

• the second by the fact that the contravariant Hom sends colimits to limits (see properties of colimit);

• the third by the assumption that each object is a compact object;

• the last by the assumption that the embedding is a full and faithful functor.

So then one defines

As filtered colimits of representable presheaves

Recall the co-Yoneda lemma that every presheaf $X\in \mathrm{PSh}(C)$ is a colimit over representable presheaves:

there is some functor $\alpha :D\to C$ such that

Remark Given that $[C^{\mathrm{op}},\mathrm{Set}]$ is the free cocompletion of $C$, $\mathrm{ind}$-$C$ defined in this way is its “free cocompletion under filtered colimits.”

To compare with the first definition, notice that indeed the formula for the hom-sets is reproduced:

Generally we have

by the fact that the hom-functor sends colimits to limits in its first argument (see properties at colimit).

By the Yoneda lemma this is

Using that colimits in $\mathrm{PSh}(C)$ are computed objectwise (see again properties at colimit) this is

Examples

• Let $\mathrm{FinVect}$ be the category of finite-dimensional vector spaces (over some field). Let $V$ be an infinite-dimensional vector space. Then $V$ can be regarded as an object of $\mathrm{ind}-\mathrm{FinVect}$ as the colimit ${\mathrm{colim}}_{V\prime \hookrightarrow V}Y(V\prime )$ over the filtered category whose objects are inclusions $V\prime \hookrightarrow V$ of finite dimensional vector spaces $V\prime$ into $V$ of the representables $Y(V\prime ):{\mathrm{FinVect}}^{\mathrm{op}}\to \mathrm{Set}$ ($Y$ is the Yoneda embedding).

• For $C$ the category of finitely presented objects of some equationally defined structure, $\mathrm{ind}\text{-}C$ is the category of all these structures.

  • The category Grp of groups is the ind-category of the category of finitely generated groups.

    • The category Ab of abelian groups is the ind-category of the category of finitely generated abelian groups.

Properties

• If $C$ is a locally small category then so is $\mathrm{ind}-C$.

• The inclusion $C\hookrightarrow \mathrm{ind}\text{-}C$ is right exact.

• a functor $F:C^{\mathrm{op}}\to \mathrm{Set}$ is in $\mathrm{ind}\text{-}C$ (i.e. is a filtered colimit of representables) precisely if the comma category $(Y,{\mathrm{const}}_F)$ (with $Y$ the Yoneda embedding) is filtered and cofinally small.

• $\mathrm{ind}\text{-}C$ admits small filtered colimits and the inclusion $\mathrm{ind}\text{-}C\hookrightarrow \mathrm{PSh}(C)$ commutes with these colimits.

• If $C$ admits finite colimits, then $\mathrm{ind}\text{-}C$ is the full subcategory of the presheaf category $\mathrm{PSh}(C)$ consisting of those functors $F:C^{\mathrm{op}}\to \mathrm{Set}$ such that $F$ is left exact and the comma category $(Y,F)$ (with $Y$ the Yoneda embedding) is cofinally small.

Applications

• One important use of categories of ind-objects is in abelian sheaf-theory: for every small abelian category $C$ the category $\mathrm{ind}\text{-}C$ is a Grothendieck category and hence a good coefficient object for abelian sheaf cohomology.

In higher category theory

In $(\mathrm{\infty },1)$-categories

There is a notion of ind-object in an (∞,1)-category.

With regard to the third of the properties listed above, notice that the comma category $(Y,{\mathrm{const}}_F)$ is the category of elements of $F$, i.e. the pullback of the universal Set-bundle $U:{\mathrm{Set}}_{*}\to \mathrm{Set}$ along $F:C^{\mathrm{op}}\to \mathrm{Set}$. This means that the forgetful functor $(Y,{\mathrm{const}}_F)\to C$ is the fibration classified by $F$.

This is the starting point for the definition at ind-object in an (∞,1)-category.

Related concepts

• ind-object / ind-object in an (∞,1)-category

• pro-object / pro-object in an (∞,1)-category

References

Ind-categories are discussed in

• Kashiwara-Schapira, Categories and Sheaves, section 6

• Grothendieck et al. SGA4.I.6 djvu file

• A. Grothendieck, Techniques de déscente et théorèmes d’existence en géométrie algébrique, II: le théorème d’existence en théorie formelle des modules, Seminaire Bourbaki 195, 1960.

See also the remarks at the beginning of section 5.3 of

• Jacob Lurie, Higher Topos Theory