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In particular the following notions are important:
Left fibrations: These are the higher analogs of fibrations in groupoids.
Anodyne morphisms: These are morphisms possessing the left lifting property with respect to all Kan fibrations. Anodyne morphisms are acyclic cofibrations in the standard model structure on simplicial sets.
The covariant model structure: This is a model structure on the over category . It is a model structure for left fibrations. It is functorial in . It is called covariant since by the -Grothendieck construction is associated to the category of covariant functors . There is also a notion of contravariant model structure where right fibrations is associated to .
The Joyal model structure: Precisely -categories are fibrant with respect to this model structure.
inner fibration and minimal fibration: These are used to develop a theory of n-categories.
cartesian fibration: These are higher analogs to Grothendieck fibrations (not necessarily in groupoids). These are defined with respect to cartesian morphisms.
categorical fibration?: These are the fibrations in the Joyal model structure on (also called model structure for quasi-categories): Morphisms of simplicial sets possessing the right lifting properties against acyclic cofibrations in this model structure. Here the cofibrations are the monomorphisms and the weak equivalences are called weak categorical equivalences. Categorical fibrations have no intrinsic meaning in -category theory. Fibrant objects in this model structure are precisely -categories.
For a general overview see model structure on simplicial sets and fibration of quasi-categories.
A morphism of simplicial sets is called
a Kan fibration if it has the right lifting property with respect to every horn inclusion.
a trivial fibration if it has the right lifting property with respect to every boundary inclusion .
a left fibration if it has the right lifting property with respect to every horn inclusion except the right outer one.
a left fibration if it has the right lifting property with respect to every horn inclusion except the left outer one.
a left fibration if it has the right lifting property with respect to every inner horn inclusion.
left anodyne if it has the left lifing property with respect to every left fibration.
right anodyne if it has the left lifing property with respect to every right fibration.
inner anodyne if it has the left lifing property with respect to every inner fibration.
minimal fibration roughly said, when the morphism is determined by its values on the boundaries.
cartesian fibration
cocartesian fibration
categorical fibration
We have the following relations of kinds of fibrations where the arrows indicate implication (e.g. an acyclic fibration is a Kan fibration).
We have the following intuition in regard to these types of fibrations
Right fibrations are the -categorical analog of fibrations in groupoids.
Left fibrations are the -categorical analog of cofibrations in groupoids.
Cartesian fibrations are the -categorical analog of fibrations (not necessarily in groupoids).
(anodyne morphisms)
Every map of simplicial sets admits a factorization into an anodyne ((left anodyne, right anodyne, inner anodyne, a cofibration) followed by a Kan fibration (left fibration, right fibration, inner fibration, trivial fibration).
The theory of left fibrations and left anodyne morphisms is dual to that of right fibrations and right anodyne morphisms; i.e. if is a left fibration (left anodyne morphisms) iff the induced map right fibrations and right anodyne morphisms.
Left fibrations are analogs to fibrations in groupoids.
Let be a functor between categories. The is a fibrations in groupoids iff the induced map is a left fibration of simplicial sets.
Compare the following lemma with Proposition 2.1.3.1
Let be a left fibration of simplicial sets. The assignment
The aim of this section is to show that left fibrations exist in abundance.
The following remark follows from a theorem of Joyal (not displayed here).
(left fibrations) 1. The projection from the over category is a left fibration.
1.The property of being a left fibration is stable under forming functor categories.
Compare the following proposition with Lemma 2.1.1.4.
Let be a left fibration of simplicial sets. Then the following statements are equivalent
is a Kan fibration.
For every edge in , the map is an isomorphism in the homotopy category of spaces.
This section is a preparation for the Grothendieck consruction for -categories.
uses the model structure on simplicially enriched categories
left- and right cone of a morphism of simplicial sets
cone point
The covariant model structure is a ‘’relative model structure’‘
Let be a simplicial set . A morphism in is called a
(C) covariant cofibration if it is a monomorphism of simplicial sets.
(W) a covariant weak equivalence if the induced map
is a categorical weak equivalence.
(F) covariant fibration if it has the right lifting property with respect to every map wich is both a covariant cofibration and a covariant equivalence.
every left anodyne map is a covariant equivalence
The covariant model structure determines a left proper, combinatorial model structure on
Every covariant fibration is a left fibration of simplicial sets
The covariant model structure is functorial in .
There is also a contravariant model structure
Requisite: Theorem 2.4.6.1: Let be a simplicial set. Then is fibrant in the Joyal model structure iff is an -category.
The exists a left proper, combinatorial model structure on the category of simplicial sets such that
(C) Cofibrations are precisely monomorphisms
(W) A map is a categorical equivalence iff is an equivalence of simplicial categories. Where denotes the functor induced via Kan extension by the cosimplicial object , Definition 1.1.5.1, HTT.
here: give proof of Proposition 1.2.7.3
is a trivial fibration.
Every -category is categorial equivalenct to a minimal -category.
Let
denote a lifting problem. Then putative solutions of this lifting problem are called homotopic relative over if they are equivalent as objects in the fiber of the map
Equivalently are homotopic relative over if there is a map
such that
and is an equivalence in the -category for every vertex of .
Let be an inner fibration of simplicial sets. is called minimal inner fibration if for every pair of maps which are homotopic relative to over .
An -category is called minimal -category if is minimal.
(…)
Every -category is equivalent to a minimal -category.
Proposition 2.3.4.5: For a simplicial set the following statements are equivalent:
the unit is an isomorphism of simplicial sets.
There is small category and an isomorphism of simpliial sets .
is a 1-category.
is an -category.
For every simplicial set and every pair of maps such that and are homotopic relative to , we have .
Let be an -category and let be a simplicial set. Then is an -category.
Let be an -category. Let .
There exists a simplicial set with the following universal mapping property: .
is an -category.
If is an -category, then the natural map is an isomorphism.
For every -category , composition with is an isomorphism of simplicial sets .
Let be a Kan complex. Then is is equivalent to an -category iff it is -truncated.
Let be an inner fibrations of simplicial sets. Let be an edge in . Then is called -cartesian if the induced map
is a trivial Kan fibration.
Every edge of a simplicial set is cartesian for an isomorphism.
Let be an inner fibration, let be the pullback of (which s then also an inner fibration). Then an edge is cartesian if ‘’its pullback’‘ is -cartesian.
(…)
Let be an inner fibration between -categories. Every identity morphism of (i.e. every degenerate edge of ) is -cartesian.
(left cancellation) Let be an inner fibration between simplicial sets. Let
Let be -cartesian. Then is -cartesian iff is -cartesian.
(…)
Let be a map of simplicial sets. Then is called a cartesian fibration if the following coditions are satisfied.
is an inner fibration.
Every edge of has a -cartesian lift.