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Consider the problem of finding the limit of the following diagram:

$$ \require{AMScd} \begin{CD} & & & & E \\ & & & & @VVV \\ && C @>>> D \\ & & @VVV \\A @>>> B \end{CD} $$

The abstract definition of the limit involves an adjunction related to collapsing the entire index category to a point. However, one could break this operation into two stages: first collapsing the upper three objects to a point reduces it to

$$ \require{AMScd} \begin{CD} & & C \times_D E \\ & & @VVV \\A @>>> B \end{CD} $$

and then we finish computing the limit as $A \times_B (C \times_D E)$.

This is a particularly convenient thing, since it implies a way to work locally with more complicated diagrams where you ultimately want a limit — i.e. take limits or perform other modifications to smaller pieces of the diagram while leaving the rest unchanged.


However, not every variation works out so nicely. If we try the same thing but instead collapse the middle three objects to a point, the intermediate diagram becomes

$$ \require{AMScd} \begin{CD} & & C \times_D E \\ & & @VVV \\A \times_B C@>>> C \end{CD} $$

So, trying to perform this operation isn't local at all; it modifies the value of the diagram at the other two vertices.

To clarify what I mean, this diagram together with the appropriate "cone" is (I believe) universal among all diagrams with "cones" of the form

$$ \require{AMScd} \begin{CD} & & \bullet &\to& E \\ & & @VVV @VVV \\\bullet @>>> \bullet & \to & D \\ \downarrow & & \downarrow & \searrow @AAA \\ A @>>> B @<<< C \end{CD} $$


It seems clear what the the abstract theory behind this sort of calculation should be; just factor the usual adjunction into a sequence of adjunctions.

But my interest in such things is very much not in the abstract — these are the sorts of operations one would like to have as a practical calculus of diagrams.

So my question is if such a calculus is known? Is there worked out how to predict and recognize which sorts of operations really should be local? Or for those operations that are not local, to easily work out how the rest of the diagram gets modified?

(and the bonus question: how much of this carries over to homotopy limits?)

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  • $\begingroup$ What precisely is the complaint about the second way of computing the limit? I don't understand what you mean by 'local'. $\endgroup$ Commented Nov 27, 2017 at 0:37
  • $\begingroup$ @Dylan: The point about locality is that manipulations on the $C \to D \leftarrow E$ part can be done in isolation (or, at least, the specific manipulation of substituting a cospan with its limit, but I imagine much more is possible) -- the modification to that subdiagram has no effect on the rest of the diagram, and conversely the rest of the diagram doesn't effect how the modification is performed. Operating on the $B \leftarrow C \to D$ subdiagram, however, doesn't have that property: collapsing it down to a point affected vertices that weren't part of the subdiagram. $\endgroup$
    – user13113
    Commented Nov 27, 2017 at 0:52
  • $\begingroup$ It seems like you're asking for some kind of analysis of when a (full) inclusion of a subdiagram $K\hookrightarrow D_1$ equalizes any functor $D_1\xrightarrow{J} C$ and its Kan extension along $D_1\xrightarrow{F}D_2$ (since a Kan extension along $D_1\to\mathbf 1$ is a (co)limit). $\endgroup$ Commented Nov 27, 2017 at 0:59
  • $\begingroup$ @Hurkyl: I don't know what it means to `collapse $B \leftarrow C \rightarrow D$ to a point, since that's not what you did: you instead 'collapsed' the top and bottom spans, i.e. computed their pullback. Like, what do you mean in general by taking some sub-diagram and 'collapsing' it? It seems more like what's happening is you're choosing some way of taking a diagram $K$ and subdividing the cone $K^{\triangleleft}$, then computing the limit (evaluation of right Kan extension at cone point) by iteratively right Kan extending along your subdivision and simultaneously restricting to initial $\endgroup$ Commented Nov 27, 2017 at 1:06
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    $\begingroup$ explicitly: suppose you have a map $K \to L$, then right Kan extending will have value at $x \in L$ given by the limit of the values in $K_{x/}$. This will be the same as one of the values you already have in $K$ if $K_{x/}$ has an initial object. So the `local' phenomena you want occurs if all the categories $K_{x/}$ have an initial object except possibly one of them. $\endgroup$ Commented Nov 27, 2017 at 1:13

2 Answers 2

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Let me try to turn my comments into an answer (I think it's also essentially what Vladimir was saying). Suppose you have some diagram $F: K \to \mathcal{C}$. To compute the limit of $F$ is the same as computing the right Kan extension $\epsilon_*F$ along the map $\epsilon: K \to \bullet$. The process you're describing is to compute this Kan extension by factoring the map $\epsilon$ into a bunch of maps $K=K_0 \to K_1 \to K_2 \to \cdots \to \bullet$ and Kan extending one at a time.

That's perfectly allowed. You'd like to keep track of the values of your diagram as you Kan extend. In general, for a functor $p: K \to L$, the value of the right Kan extension $p_*F$ at a point $x \in L$ is given by the limit over the category $K_{x/}$, i.e. the category whose objects are pairs $(k, x \to p(k))$ and whose morphisms are morphisms in $K$ making the appropriate diagram commute.

In general one might ask: when is a limit of a functor $G$ over some diagram $D$ given by just one of the values $G(d)$? A sufficient condition for this to occur is that $d \in D$ be initial.

Putting these two facts together we learn that:

  • $p_*F(x)$ is given by a known value of $F$ if $K_{x/}$ has an initial object.

Now you'd like some explicit procedure, I guess, for computing the limit over $K$ in this iterative way where you don't have to change too much at once. Here is one way that works. For ease let's take a skeletal, finite $K$.

  1. First consider the diagram $K_1$ obtained from $K$ by asking that every endomorphism be the identity. The right Kan extension to this step computes the 'fixed points' of each object under the action of the endomorphisms. If you want, you could do it one object at a time.
  2. Now begin collapsing parallel arrows one step at a time. This will always be a collapse of the desired type. Indeed, if $a\rightrightarrows b$ is a pair of arrows in $K_i$ and we collapse them to build $K_{i+1}$, then the overcategories $(K_{i+1})_{x/}$ will evidently have initial object $x$ if $x \ne a$. If $x = a$ then we'll be computing an equalizer.
  3. Now you've got a category $K_N$ where every object has only the identity endomorphism, and there is at most one arrow between any two objects. So you've got a poset! Now you can begin pruning exactly as you did in your example. Arrange the poset by height. Say it has height $n$. If $n$ is zero, then you've got a discrete poset- take the product. Otherwise, if you see two objects of height $(n-1)$ which hit an object of height $n$, form $K_{N+1}$ by collapsing those three objects to a point. This procedure replaces the three objects by the pullback and changes nothing else. Keep doing that until there are no more such objects of height $n$. Either you've decreased the height to $(n-1)$, or there are objects of height $n$ with only one thing of height $(n-1)$ hitting it. Taking each in turn, collapse those pairs to a point. This won't do anything except delete those height $n$ values from your diagram. Now you have something of height $(n-1)$. Repeat until you get down to height 0, then take the product of everything you see.

There are many variations on this theme... you could do things in a different order, or you could embed into a larger diagram which is often convenient, etc. etc.

Of course, there's also the standard formula for a limit as an equalizer of two products, but I imagine you knew that already.

Also- everything I said works for homotopy limits over ordinary categories. If you want to do homotopy limits over an $\infty$-category, you can still do something like this. In fact, said in the language of $\infty$-categories or quasicategories, this whole procedure is maybe more evident: take your quasicategory, which is a simplicial set $K$, and write it as an iterated pushout along cell inclusions (maybe transfinitely many). Then a homotopy colimit over $K$ can be computed by iteratively by using pushouts, or if you come across an empty diagram you'll need an initial object, and then taking filtered colimits along the way. One can take care of limits by working in the opposite category.

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This sort of calculus is central to the abstract study of homotopy limits via derivators. See this paper and this one for some examples of "detection lemmas" that decompose limits using Kan extensions in various ways; they all follow from the calculus of homotopy exact squares.

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