Proof

We first prove the Hom-characterization from the definition. Given $(i, \phi : L(x, i) \to y)$, we get $\alpha(\phi) := R\phi \circ \eta_{x, i} : x \to R y$. The definition demands that this is an isomorphism. To see naturality, let $\chi : y \to z$. Then

Now let $\alpha$ be given. Then we define $\eta_{x, i} = \alpha(i, id) : x \to RL(x, i)$. By naturality, $\alpha(i, \phi) = R\phi \circ \eta_{x, i}$. Then invertibility of $\alpha$ proves the condition in the definition.

Proof

We use the characterization in theorem .

First of all, note that the type of the object part of $K$ is the same as the type of $(I, L)$; let us identify these. Next, note that $Hom_{Fam(D)}(K c, J d) \cong \Sigma(i \in I(x)).Hom_D(L(c, i), d)$.

So to show that the characterization here implies the definition, we simply need to forget functoriality of $K$ and naturality in $c$.

Conversely, assume that the object part of $K$ is given. Then we construct a morphism part such that $\alpha$ is natural in $c$.

Take $\phi : Hom_C(c, c')$. We want $K\phi : Hom_{Fam(D)}(Kc, Kc')$, i.e.

i.e.

so we can take $K(\phi, i') = \alpha^{-1}(\eta_{c', i'} \circ \phi)$. Denote the components of $K\phi$ as $I\phi : I(c') \to I(c)$ and $L\phi : (i' \in I(i')) \to Hom_D(L(c, I(\phi, i')), L(c', i'))$.

• This preserves the identity: $K(id) = \lambda i.\alpha^{-1}(\eta_{x, i} \circ id) = \lambda i.(i, id)$.

• This preserves composition. Let $\phi : Hom_C(c, c')$ and $\chi : Hom_C(c', c'')$. With some abuse of notation:

  $K \chi \circ K \phi = (I\phi \circ I\chi, \lambda i''.L(\chi, i'') \circ L(\phi, I(\chi, i'')))$

  $= \lambda i''.(I(\phi, I(\chi, i'')), L(\chi, i'') \circ L(\phi, I(\chi, i'')))$

  $= \lambda i''.JL(\chi, i'') \circ (I(\phi, I(\chi, i'')), L(\phi, I(\chi, i'')))$

  $= \lambda i''.JL(\chi, i'') \circ K(\phi, I(\chi, i''))$

  $= \lambda i''.JL(\chi, i'') \circ \alpha^{-1}(\eta_{c', I(\chi, i'')} \circ \phi)$

  $= \lambda i''.\alpha^{-1}(RL(\chi, i'') \circ \alpha(I(\chi, i''), id_{c'}) \circ \phi)$

  $= \lambda i''.\alpha^{-1}(\alpha(I(\chi, i''), L(\chi, i'')) \circ \phi)$

  $= \lambda i''.\alpha^{-1}(\alpha(K(\chi, i'')) \circ \phi)$

  $= \lambda i''.\alpha^{-1}(\eta_{c'', i''} \circ \chi \circ \phi)$.

Now we prove that $\alpha$ is natural in $c$. Let $\psi : Hom_{Fam(D)}(Kc', Jd)$ and $\phi : Hom_{C}(c, c')$. Note that $\psi$ is essentially of the form $(i', \chi)$ for $i' \in I(c')$ and $\chi \in \Hom_D(L(c', i), d)$. With more abuse of notation:

$\alpha(\psi \circ K\phi) = \alpha((i', \chi) \circ K\phi) = \alpha(I(\phi, i'), \chi \circ L(\phi, i'))$

$= \alpha(J\chi \circ K(\phi, i')) = \alpha(J\chi \circ \alpha^{-1}(\eta_{c', i'} \circ \phi))$

$= R\chi \circ \eta_{c', i'} \circ \phi = \alpha(J\chi \circ (i', id_{c'})) \circ \phi = \alpha(i', \chi) \circ \phi = \alpha(\psi) \circ \phi$.