nLab quasi-category

Context

$(\infty,1)$-Category theory

(∞,1)-category theory

Contents

Idea

The notion of quasi-category is a geometric model for (∞,1)-category.

In analogy to how a Kan complex is a model in terms of simplicial sets of an ∞-groupoid – also called an (∞,0)-category – a quasi-category is a model in terms of simplicial sets of an (∞,1)-category.

Definition

Definition

A quasi-category or weak Kan complex is a simplicial set $C$ satisfying the following equivalent conditions

• all inner horns in $C$ have fillers. This means that the lifting condition given at Kan complex is imposed only for horns $\Lambda^i[n]$ with $0 \lt i \lt n$.

• the morphism of simplicial sets

$sSet(\Delta[2],C) \to sSet(\Lambda^1[2],C)$

(induced from the inner horn inclusion $\Lambda^1[2] \to \Delta[2]$) is an acyclic Kan fibration.

The equivalence of these two definitions is due to Andre Joyal and recalled as HTT, corollary 2.3.2.2.

Remark

The second condition says manifestly that a quasi-category is a simplicial set in which composition of any two composable edges is defined up to a contractible space of choices. This is the coherence law on composition.

Definition

An algebraic quasi-category is a quasi-category equipped with a choice of inner horn fillers.

While quasi-categories provide a geometric definition of higher categories, algebraic quasi-categories provide an algebraic definition of higher categories. For more details on this see model structure on algebraic fibrant objects.

Remark on terminology

In older literature, such as The Joy of Cats, the term “quasicategory” was sometimes used for a “very large” category whose objects are large categories or otherwise built out of proper classes, but nowadays this usage is fairly archaic. See also metacategory

Properties

Relation to simplicially enriched categories

The homotopy coherent nerve relates quasi-categories with another model for $(\infty,1)$-categories: simplicially enriched categories.

Higher associahedra in quasi-categories

While the geometric definition of (∞,1)-category in terms of quasi-categories elegantly captures all the higher categorical data automatically, it may be of interest in applications to explicitly extract the associators and higher associators encoded by this structure, that would show up in any algebraic definition of the same categorical structure, such as algebraic quasi-categories.

For a discussion of this see

• Emily Riehl, Associativity data in an $(\infty,1)$-category (pdf blog)

Examples

The two basic examples for quasi-categories are

Since the nerve of a category is a Kan complex iff the category is a groupoid, quasi-categories are a minimal common generalization of Kan complexes and nerves of categories.

By the homotopy hypothesis-theorem every Kan complex arises, up to equivalence, as the fundamental ∞-groupoid of a topological space.

Analogously, every directed topological space $X$ has naturally a fundamental (∞,1)-category given by a quasi-category whose $k$-cells are maps $\Delta^k_{Top} \to X$ that map the 1-skeleton of the topological simplex in an order-preserving way to directed paths in $X$.

The directed homotopy theory that would state that this or a similar construction exhausts all quasicategories up to equivalence, does not quite exist yet.

Constructions in quasi-categories

The point of quasi-categories is that they are supposed to provide a fully homotopy-theoretic refinement of the ordinary notion of category. In particular, all the familiar constructions of category theory have natural analogs in the context of quasi-categories. See for instance

One may try to further weaken the filler conditions in order to describe (∞,n)-categories for $n \gt 1$. One approach along these lines is the theory of weak complicial sets.

Or one may change the shape category to pass from simplicial sets to cellular sets. A quasi-category-like definition of (∞,n)-categories on these – n-quasicategories – is discussed at model structure on cellular sets.

References

Quasi-categories were originally defined in

• Michael Boardman, Rainer Vogt, Homotopy invariant algebraic structures on topological spaces, Lecture Notes in Mathematics, Vol. 347. Springer-Verlag, 1973.

They occured as weak Kan complexes in

• Rainer Vogt, Homotopy limits and colimits, Math. Z., 134, (1973), 11–52.

Vogt’s main theorem involved a category of homotopy coherent diagrams defined on a topologically enriched category and showed it was equivalent to a quotient category of the category of (commutative) diagrams on the same category.

• J.-M. Cordier, Sur la notion de diagramme homotopiquement cohérent, Cahiers de Top. Géom. Diff., 23, (1982), 93 –112,

defined the homotopy coherent nerve of any simplicially enriched category. This generalised the nerve of an ordinary category. In

• J.-M. Cordier and Tim Porter, Vogt’s theorem on categories of homotopy coherent diagrams, Math. Proc. Cambridge Philos. Soc., 100, (1986), 65–90,

it was shown that this homotopy coherent nerve was a quasi-category if the simplicial enrichment was by Kan complexes.

A systematic study of SSet-enriched categories in this context is in

• J-M Cordier, Tim Porter Homotopy coherent category theory Trans. Amer. Math. Soc. 349 (1997), no. 1, 1-54. (pdf)

The importance of quasi-categories as a basis for category theory has been particularly emphasized in the work by André Joyal

• André Joyal, Quasi-categories and Kan complexes, J. Pure Appl. Algebra, 175 (2002), 207-222.

For several years Joyal has been preparing a textbook on the subject. This still doesn’t quite exist, but an extensive writeup of lecture notes does:

and more recently, with more details

Meanwhile Jacob Lurie, building on Joyal’s work, has considerably pushed the theory further. A comprehensive discussion of the theory of $(\infty,1)$-categories in terms of the models quasi-category and simplicially enriched category is in

An overview of the material there is contained in

The relation between quasi-categories and simplicially enriched categories was discussed in detail in

Related reviews includes

An in-depth study of adjunctions between quasi-categories and the monadicity theorem is given in

Discussion

A previous version of this entry led to the following discussion.

Stephen Gaito: If we want to weaken this even further to provide a simplicial model of, for example, a (∞,2)-category, how would we do this?

Would we apply the lifting condition on all but three of the indices… and if so which three? (The first, last and ????)

Mike Shulman: You may be looking for something along the lines of a weak complicial set.

Revised on March 24, 2015 19:22:30 by Adeel Khan (77.9.48.237)