Proof

Let $I$ be a finite connected category and $F\colon I\to C$ a functor. Since $I$ is connected, it is inhabited; choose some object $x_0\in I$. For each object $x\in I$, let $\ell(x)$ be the length of the shortest zigzag from $x_0$ to $x$. Now order the objects of $I$ as $x_0, x_1, \dots, x_n$ such that for all $i$ we have $\ell(x_i) \le \ell(x_{i+i})$.

Now we inductively define objects $P_i\in C$, for $0\le i\le n$, with projections $p_{i j}\colon P_i \to F(x_j)$ for $j\le i$. We begin with $P_0 = x_0$ and $p_{0 0}= 1_{x_0}$. Assuming $P_i$ and $p_{i j}$ defined, choose a zigzag from $x_0$ to $x_{i+1}$ of minimal length, say

By our choice of the ordering of the objects of $I$, we have $y_k = x_j$ for some $j\le i$, and thus we have $q = p_{i j}\colon P_i \to y_k$.

If the final arrow $y_k \leftrightarrow x_{i+1}$ in the zigzag is directed as $y_k \to x_{i+1}$, then let $P_{i+1} = P_i$, let $p_{i+1, i+1}$ be the composite $P_i \xrightarrow{q} F(y_k) \to F(x_{i+1})$, and keep the other $p_{i j}$ unchanged. On the other hand, if $y_k \leftrightarrow x_{i+1}$ is directed as $y_k \leftarrow x_{i+1}$, let $P_{i+1}$ be the pullback

and define $p_{i+1,j}$ for $j\le i$ by composition with $P_{i+1}\to P_i$.

At the end of this procedure, we have an object $P_n$ with projections $p_{n,j}\colon P_n \to F(x_j)$ for all objects $x_j\in I$. Now we order the morphisms in $I$ as $g_0,\dots,g_m$ and define, inductively, an object $Q_i$ with a morphism $q_i\colon Q_i \to P_n$. We begin with $Q_0 = P_n$ and $q_0 = 1_{P_n}$. Given $Q_i$ and $q_i$, we let $e\colon Q_{i+1} \to Q_{i}$ be the equalizer of $F(g_{i+1}) \circ p_{n,?} \circ q_i$ and $p_{n,?} \circ q_i$, where the ?s denote the indices of the objects that are the source and target of $g_{i+1}$. We then set $q_{i+1} = q_i \circ e$.

At the end of this procedure, we have an object $Q_{m+1}$ together with a cone over the diagram $F$, which is easily verified to be a limit of $F$.

Proof

The wide pullback of the diagram $f_i: X_i \to X$ where $f_i = 1_X$ for all $i$ is clearly $X$, as is the equalizer of the pair of identity arrows. Since the product functor $C \times C \to C$ preserves arbitrary limits, we see that

i.e., $X \times -$ preserves wide pullbacks. The same line of argument shows $X \times -$ preserves equalizers, so $X \times -$ preserves connected limits.

The functor $X \times -$ carries a canonical comonad structure, whose category of coalgebras is $C/X$. The forgetful functor $C/X \to C$ is comonadic, and thus preserves and reflects any class of limits preserved by the comonad $X \times -$. Thus $\sum_X: C/X \to C$ preserves and reflects all connected limits.

Proof

The forward direction is clear since wide pullbacks are examples of connected limits. Now suppose $G\colon C \to D$ preserves wide pullbacks. Then

preserves wide pullbacks for every object $d$ of $D$. Put $I = hom(d, G 1)$. The underlying functor

reflects and preserves connected limits and in particular wide pullbacks, so that the evident lift

preserves wide pullbacks. It also preserves the terminal object, hence by this proposition it preserves arbitrary limits. Therefore the composite

preserves connected limits, for every object $d$. Since this is the same composite as in (1), and since the representables $\hom(d, -)$ jointly reflect arbitrary limits, we conclude that $G$ preserves connected limits.