Accessible category explained

The theory of accessible categories is a part of mathematics, specifically of category theory. It attempts to describe categories in terms of the "size" (a cardinal number) of the operations needed to generate their objects.

The theory originates in the work of Grothendieck completed by 1969, and Gabriel and Ulmer (1971). It has been further developed in 1989 by Michael Makkai and Robert Paré, with motivation coming from model theory, a branch of mathematical logic.A standard text book by Adámek and Rosický appeared in 1994.[1] Accessible categories also have applications in homotopy theory.[2] [3] Grothendieck continued the development of the theory for homotopy-theoretic purposes in his (still partly unpublished) 1991 manuscript Les dérivateurs.[4] Some properties of accessible categories depend on the set universe in use, particularly on the cardinal properties and Vopěnka's principle.[5]

-directed colimits and -presentable objects

Let

\kappa

be an infinite regular cardinal, i.e. a cardinal number that is not the sum of a smaller number of smaller cardinals; examples are

\aleph0

(aleph-0), the first infinite cardinal number, and

\aleph1

, the first uncountable cardinal). A partially ordered set

(I,\leq)

is called

\kappa

-directed
if every subset

J

of

I

of cardinality less than

\kappa

has an upper bound in

I

. In particular, the ordinary directed sets are precisely the

\aleph0

-directed sets.

Now let

C

be a category. A direct limit (also known as a directed colimit) over a

\kappa

-directed set

(I,\leq)

is called a

\kappa

-directed colimit
. An object

X

of

C

is called

\kappa

-presentable if the Hom functor

\operatorname{Hom}(X,-)

preserves all

\kappa

-directed colimits in

C

. It is clear that every

\kappa

-presentable object is also

\kappa'

-presentable whenever

\kappa\leq\kappa'

, since every

\kappa'

-directed colimit is also a

\kappa

-directed colimit in that case. A

\aleph0

-presentable object is called finitely presentable.

Examples

\kappa

-presentable objects are the sets of cardinality smaller than

\kappa

.

\kappa

, the

\kappa

-presentable objects are precisely the groups with cardinality smaller than

\kappa

.

R

, the finitely presentable objects are precisely the finitely presented modules.

-accessible and locally presentable categories

The category

C

is called

\kappa

-accessible
provided that:

C

has all

\kappa

-directed colimits

C

contains a set

P

of

\kappa

-presentable objects such that every object of

C

is a

\kappa

-directed colimit of objects of

P

.

An

\aleph0

-accessible category is called finitely accessible.A category is called accessible if it is

\kappa

-accessible for some infinite regular cardinal

\kappa

. When an accessible category is also cocomplete, it is called locally presentable.

A functor

F:C\toD

between

\kappa

-accessible categories is called

\kappa

-accessible
provided that

F

preserves

\kappa

-directed colimits.

Examples

R

-Mod of (left)

R

-modules is locally finitely presentable for any ring

R

.

\aleph1

-accessible.

\aleph1

-presentable objects are models with a countable number of elements.

Theorems

One can show that every locally presentable category is also complete.[6] Furthermore, a category is locally presentable if and only if it is equivalent to the category of models of a limit sketch.[7]

Adjoint functors between locally presentable categories have a particularly simple characterization. A functor

F:C\toD

between locally presentable categories:

Notes and References

  1. Adamek/Rosický 1994
  2. J. Rosický "On combinatorial model categories", arXiv, 16 August 2007. Retrieved on 19 January 2008.
  3. Rosický, J. "Injectivity and accessible categories." Cubo Matem. Educ 4 (2002): 201-211.
  4. (Les Dérivateurs: Texte d'Alexandre Grothendieck. Édité par M. Künzer, J. Malgoire, G. Maltsiniotis)
  5. Adamek/Rosický 1994, chapter 6
  6. Adamek/Rosický 1994, remark 1.56
  7. Adamek/Rosický 1994, corollary 1.52