nLab (infinity,1)-category of (infinity,1)-presheaves

Contents

Context

$(\infty,1)$ -Category theory

$(\infty,1)$ -Topos Theory

Definition
Properties

Models
Limits and colimits
As the free completion under colimits
Relation to slicing

$(\infty,1)$ -subcategories of $(\infty)$ -presheaf categories

Locally presentable $(\infty,1)$ -categories
$(\infty,1)$ -Sheaf $(\infty,1)$ -categories

Related concepts
References

Definition

For ∞Grpd the (∞,1)-category of ∞-groupoids, and for $S$ a (∞,1)-category (or in fact any simplicial set), an $(\infty,1)$ -presheaf on $S$ is an $(\infty,1)$ -functor

F : S^{op} \to \infty Grpd \,.

The $(\infty,1)$ -category of $(\infty,1)$ -presheaves is the (∞,1)-category of (∞,1)-functors

PSh_{(\infty,1)}(S) := Func(S^{op}, \infinity Grpd) \,.

Properties

Models

A model for an $(\infty,1)$ -presheaf categories is the model structure on simplicial presheaves. See also the discussion at models for ∞-stack (∞,1)-toposes.

Proposition

For $C$ a simplicially enriched category with Kan complexes as hom-objects, write $[C^{op}, sSet_{Quillen}]_{proj}$ and $[C^{op}, sSet_{Quillen}]_{inj}$ for the projective or injective, respectively, global model structure on simplicial presheaves. Write $(-)^\circ$ for the full sSet-enriched subcategory on fibrant-cofibrant objects, and $N(-)$ for the homotopy coherent nerve that sends a Kan-complex enriched category to a quasi-category.

Then there is an equivalence of quasi-categories

PSh(N(C)) \simeq N ([C^{op}, sSet_{Quillen}]_{proj})^\circ \,.

Similarly for the injective model structure.

Proof

This is a special case of the more general statement that the model structure on functors models an (∞,1)-category of (∞,1)-functors. See there for more details.

Notice that the result in particular means that any $(\infty,1)$ -presheaf – an “ $\infty$ -pseudofunctor” – may be straightened or rectified to a genuine sSet-enriched functor, that respects horizontal compositions strictly.

Limits and colimits

In an ordinary category of presheaves, limits and colimits are computed objectwise, as described at limits and colimits by example. The analogous statement is true for (∞,1)-limits and colimits in an $(\infty,1)$ -category of $(\infty,1)$ -presheaves.

This is a special case of the general existence of limits and colimits in an (∞,1)-category of (∞,1)-functors. See there for more details.

Corollary

For $C$ a small $(\infty,1)$ -category, the $(\infty,1)$ -category $PSh(C)$ admits all small limits and colimits.

See around HTT, cor. 5.1.2.4.

As the free completion under colimits

An ordinary category of presheaves on a small category $C$ is the free cocompletion of $C$ , the free completion under forming colimits.

The analogous result holds for $(\infty,1)$ -category of $(\infty,1)$ -presheaves.

Lemma

Let $C$ be a small quasi-category and $j : S \to PSh(C)$ the (∞,1)-Yoneda embedding.

The identity (∞,1)-functor $Id : PSh(C) \to PSh(C)$ is the left (∞,1)-Kan extension of $j$ along itself.

Proof

This is HTT, lemma 5.1.5.3.

For $D$ a quasi-category with all small colimits, write $Func^L(PSh(C),D) \subset Func(PSh(C),D)$ for the full sub-quasi-category of the (∞,1)-category of (∞,1)-functors on those that preserve small colimits.

Lemma

Composition with the Yoneda embedding $j : C \to PSh(C)$ induces an equivalence of quasi-categories

Func^L(PSh(C),D) \to Func(C,D) \,.

Proof

This is HTT, theorem 5.1.5.6.

In terms of the model given by the model structure on simplicial presheaves, this is statement made in

Dan Dugger, Universal homotopy theories ,

which gives that article its name.

Definition

Let $A$ and $B$ be model categories, $D$ a plain category and

\array{ D &\stackrel{r}{\to}& A \\ & \searrow_\gamma \\ && B }

two plain functors. Say that a model-category theoretic factorization of $\gamma$ through $A$ is

a Quillen adjunction $(L \dashv R) : A \stackrel{\overset{L}{\to}}{\underset{R}{\leftarrow}} B$
a natural weak equivalence $\eta : L \circ r \to \gamma$

$\array{ D &&\stackrel{r}{\to}&& A \\ & \searrow_\gamma &{}^\eta\swArrow& \swarrow_L \\ && B } \,.$

Let the category of such factorizations have morphisms $((L \dashv R), \eta ) \to ((L' \dashv R'), \eta' )$ given by natural transformations $L \to L'$ such that for all all objects $d \in D$ the diagrams

\array{ L\circ r(d) &&\to&& L'\circ r(d) \\ & {}_{\eta_{d}}\searrow && \swarrow_{\eta'_{d}} \\ && \gamma() }

commutes.

Notice that the (∞,1)-category presented by a model category – at least by a combinatorial model category – has all (∞,1)-categorical colimits, and that the Quillen left adjoint functor $L$ presents, via its derived functor, a left adjoint (∞,1)-functor that preserves $(\infty,1)$ -categorical colimits. So the notion of factorization as above is really about factorizations through colimit-preserving $(\infty,1)$ -functors into $(\infty,1)$ -categories that have all colimits.

Theorem

(model category presentation of free $(\infty,1)$ -cocompletion)

For $C$ a small category, the projective global model structure on simplicial presheaves $[C^{op}, sSet]_{proj}$ on $C$ is universal with respect to such factorizations of functors out of $C$ :

every functor $C \to B$ to any model category $B$ has a factorization through $[C^{op}, sSet]_{proj}$ as above, and the category of such factorizations is contractible.

Proof

This is theorem 1.1 in

Dan Dugger, Universal homotopy theories .

The proof is on page 30.

To produce the factorization $[C^{op},sSet] \to B$ given the functor $\gamma$ , first notice that the ordinary Yoneda extension $[C^{op},Set] \to B$ would be given by the left Kan extension given by the coend formula

F \mapsto \int^{c \in C} \gamma(c) \cdot F(c) \,,

where the dot in the integrand is the tensoring of cocomplete category $B$ over Set. To refine this to a left Quillen functor $L : [C^{op},sSet] \to B$ , choose a cosimplicial resolution?

\Gamma : C \to [\Delta,B]

of $\gamma$ . Then set

L : F \mapsto \int^{c \in C} \int^{[n] \in \Delta} \Gamma^n(c) \cdot F_n(c) \,.

The right adjoint $R : B \to [C^{op},sSet]$ of this functor is given by

R(X) : c \mapsto Hom_B(\Gamma^\bullet(c), X) \,.

For $(L \dashv R) : [C^{op}, sSet]_{proj} \stackrel{\to}{\leftarrow} B$ to be a Quillen adjunction, it is sufficient to check that $R$ preserves fibrations and acyclic fibrations. By definition of the projective model structure this means that for every (acyclic) fibration $b_1 \to b_2$ in $B$ we have for every object $c \in C$ that that

Hom_C(\Gamma^\bullet(c), b_1 \to b_2)

is an (acyclic) fibration of simplicial sets. But this is one of the standard properties of cosimplicial resolution?s.

Finally, to find the natural weak equivalence $\eta : L \circ j \simeq \gamma$ , write $j : C \to [C^{op},sSet]$ for the Yoneda embedding and notice that by Yoneda reduction it follows that for $x \in C$ we have

L(j(x)) = \int^{c \in C} \int^{[n] \in \Delta} \Gamma^n(c) \cdot C(c,x) = \Gamma^0(x)

(where equality signs denote isomorphisms).

By the very definition of cosimplicial resolutions, there is a natural weak equivalence $\Gamma(x) \stackrel{\simeq}{\to}$ . We can take this to be the component of $\eta$ .

Corollary

The (∞,1)-Yoneda embedding $j : C \to PSh(C)$ generates $PSh(C)$ under small colimits:

a full (∞,1)-subcategory of $PSh(C)$ that contains all representables and is closed under forming $(\infty,1)$ -colimits is already equivalent to $PSh(C)$ .

Proof

This is HTT, corollary 5.1.5.8.

Relation to slicing

The following analog of the corresponding result for 1-categories of presheaves holds for $(\infty,1)$ -presheaves. See functors and comma categories.

Proposition

(slicing commutes with passing to presheaves)

Let $\mathcal{C}$ be a small (∞,1)-category and $p \colon \mathcal{K} \to \mathcal{C}$ a diagram.

Write $\mathcal{C}_{/p}$ and $PSh_\infty(\mathcal{C})/_{y p}$ for the corresponding over categories, where $y \colon \mathcal{C} \to PSh_\infty(\mathcal{C})$ is the (∞,1)-Yoneda embedding.

Then we have an equivalence of (∞,1)-categories

PSh_\infty(\mathcal{C}_{/p}) \stackrel{\simeq}{\to} PSh_\infty(\mathcal{C})_{/y p} \,.

This appears as HTT, 5.1.6.12.

$(\infty,1)$ -subcategories of $(\infty)$ -presheaf categories

Locally presentable $(\infty,1)$ -categories

A reflective (∞,1)-subcategory of an $(\infty,1)$ -category of $(\infty,1)$ -presheaves is called a presentable (∞,1)-category.

$(\infty,1)$ -Sheaf $(\infty,1)$ -categories

If that left adjoint (∞,1)-functor to the embedding of the reflective (∞,1)-subcategory furthermore preserves finite limits, then the subcategory is an (∞,1)-category of (∞,1)-sheaves: an (∞,1)-topos

Related concepts

Locally presentable categories: Cocomplete possibly-large categories generated under filtered colimits by small generators under small relations. Equivalently, accessible reflective localizations of free cocompletions. Accessible categories omit the cocompleteness requirement; toposes add the requirement of a left exact localization.

$\phantom{A}$ (n,r)-categories $\phantom{A}$	$\phantom{A}$ toposes $\phantom{A}$	locally presentable	loc finitely pres	localization theorem	free cocompletion	accessible
(0,1)-category theory	locales	suplattice	algebraic lattices	Porst’s theorem	powerset	poset
category theory	toposes	locally presentable categories	locally finitely presentable categories	Adámek-Rosický‘s theorem	presheaf category	accessible categories
model category theory	model toposes	combinatorial model categories		Dugger's theorem	global model structures on simplicial presheaves	n/a
(∞,1)-category theory	(∞,1)-toposes	locally presentable (∞,1)-categories		Simpson’s theorem	(∞,1)-presheaf (∞,1)-categories	accessible (∞,1)-categories

References

This is the topic of section 5.1 of

Jacob Lurie, Higher Topos Theory

Last revised on October 10, 2021 at 18:16:50. See the history of this page for a list of all contributions to it.

nLab (infinity,1)-category of (infinity,1)-presheaves

Context

$(\infty,1)$ -Category theory

$(\infty,1)$ -Topos Theory

Background

Definitions

Characterization

Morphisms

Extra stuff, structure and property

Models

Constructions

Contents

Definition

Properties

Models

Proposition

Proof

Limits and colimits

Corollary

As the free completion under colimits

Lemma

Proof

Lemma

Proof

Definition

Theorem

Proof

Corollary

Proof

Relation to slicing

Proposition

$(\infty,1)$ -subcategories of $(\infty)$ -presheaf categories

Locally presentable $(\infty,1)$ -categories

$(\infty,1)$ -Sheaf $(\infty,1)$ -categories

Related concepts

References

nLab (infinity,1)-category of (infinity,1)-presheaves

Context

(∞,1)(\infty,1)-Category theory

(∞,1)(\infty,1)-Topos Theory

Background

Definitions

Characterization

Morphisms

Extra stuff, structure and property

Models

Constructions

Contents

Definition

Properties

Models

Proposition

Proof

Limits and colimits

Corollary

As the free completion under colimits

Lemma

Proof

Lemma

Proof

Definition

Theorem

Proof

Corollary

Proof

Relation to slicing

Proposition

(∞,1)(\infty,1)-subcategories of (∞)(\infty)-presheaf categories

Locally presentable (∞,1)(\infty,1)-categories

(∞,1)(\infty,1)-Sheaf (∞,1)(\infty,1)-categories

Related concepts

References

$(\infty,1)$ -Category theory

$(\infty,1)$ -Topos Theory

$(\infty,1)$ -subcategories of $(\infty)$ -presheaf categories

Locally presentable $(\infty,1)$ -categories

$(\infty,1)$ -Sheaf $(\infty,1)$ -categories