I am reading the paper colimits of accessible categories. In the introduction, the authors summarize what is known about limits and colimits of accessible categories. I believed that there was something known about homotopy limits or colimits of accessible categories as well. Browsing zbMATH or MR give nothing for "accessible category AND ((ho)motopy) limit". Could I have a reference please (or better keywords) ?
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$\begingroup$ What do you mean by homotopy limit? If you are referring to pseudolimits (resp. lax limits) in the 2-category of accessible categories, they are known to exist and be computed as pseudolimits (resp. lax limits) of ordinary categories. $\endgroup$– Zhen LinCommented Nov 19, 2013 at 9:58
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$\begingroup$ @ZhenLin The meaning of homotopy limit was a part of the question. $\endgroup$– Philippe GaucherCommented Nov 19, 2013 at 10:06
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$\begingroup$ There have been a number of math overflow questions about homotopy colimits, including this one which contains many good references: mathoverflow.net/questions/454/references-for-homotopy-colimit. That said, I don't know of an exact place which summarizes their properties like the paper of Pare and Rosicky. My best guess would be Dugger's survey article $\endgroup$– David WhiteCommented Nov 19, 2013 at 14:12
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I can only offer a partial answer:
First, have a look at an explicit description of limits of categories.
Namely, strong (or pseudo-) limits can be modelled as the category of cartesian sections into the Grothendieck construction. Denote this category $\Gamma_{\mathrm{Gr}(F)}$.
[Part I] Existence of $\kappa$-directed limits:
Now; Let $F:X\to\mathrm{Cat}$ be a strong functor such that all the functors $F(f):F(x)\to F(y)$ involved are $\kappa$-accessible. Then $\kappa$-filtered colimits can be computed pointwise.
More generally, consider a functor $\gamma:I\to \Gamma_{\mathrm{Gr}(F)}$ and assume all the functors $F(f)$ to preserve $I$-indexed colimits. Then for every $x\in X$ we get a functor $\gamma_{(-)}(x):I\to F(x)$. Then take $\gamma^*:X\to\Gamma_{\mathrm{Gr}(F)}$ to be the functor given on objects by $$x\mapsto \mathrm{colim}_i\,\gamma_i(x).$$ The morphism part of this functor is defined using the universal properties of the colimits involved. If i'm not mistaken, $\gamma^*$ is a colimit of $\gamma$ and again a cartesian section.
As a special case take $I$ to be any $\kappa$-directed poset.
[Part II] Generated by $\kappa$-compact objects?
I'm not so sure about the second part of the definition of $\kappa$-accessible category.
My idea would be to consider the case where all the $F(f)$ preserve $\kappa$-compact objects. This is certainly the case in the article you linked to as Paré and Rosický consider fully faithful functors.
The problem now is that i don't see how one could extend a $\kappa$-compact object in one fiber $F(x)$ to a global cartesian section: Even though the stalks/fibers might be generated by $\kappa$-compact objects i don't know how to even of the existence of such objects in the category of (cartesian) sections.
But perhaps one of the other posters can say something in this direction.
answered Nov 26, 2013 at 16:05