10.
The inverse image functor
\[ R_{-1}\colon (\mathcal{P}(B),\subset )\to (\mathcal{P}(A),\subset ) \]
associated to $R$ is essentially surjective.
11.
The codirect image functor
\[ R_{*}\colon (\mathcal{P}(A),\subset )\to (\mathcal{P}(B),\subset ) \]
associated to $R$ is fully faithful.
12.
For each pair of relations $S,T\colon X\mathrel {\rightrightarrows \kern -9.5pt\mathrlap {|}\kern 6pt}A$, the following condition is satisfied:
- (★)
If $R\mathbin {\diamond }S\subset R\mathbin {\diamond }T$, then $S\subset T$.
13.
There exists an injective function $f\colon A\hookrightarrow B$ satisfying the following conditions:
-
(a)
We have $\operatorname {\mathrm{Gr}}(f)\subset R$.
-
(b)
The diagram
commutes.
14.
We have
In other words, we have
\[ U=\underbrace{\left\{ a\in A\ \middle |\ R(a)\subset R(U)\right\} }_{=R_{-1}(R_{!}(U))} \]
for each $U\in \mathcal{P}(A)$.
15.
We have
In other words, we have
\[ U=\underbrace{\left\{ a\in A\ \middle |\ \begin{aligned} & \text{there exists some $b\in R(a)$}\\ & \text{such that we have $R^{-1}(b)\subset U$} \end{aligned} \right\} }_{=R^{-1}(R_{*}(U))} \]
for each $U\in \mathcal{P}(A)$.
We will prove this by showing:
This follows from Item 17 of Proposition 8.7.1.1.4.
We claim that Item 1 and Item 2 are equivalent:
-
•
Item 1$\implies $Item 2: Let $U,V\in \mathcal{P}(A)$ and consider the diagram
By Remark 8.7.1.1.3, we have
\begin{align*} R_{!}(U) & = R\mathbin {\diamond }U,\\ R_{!}(V) & = R\mathbin {\diamond }V. \end{align*}
Now, if $R\mathbin {\diamond }U=R\mathbin {\diamond }V$, i.e. $R_{!}(U)=R_{!}(V)$, then $U=V$ since $R$ is assumed to be a monomorphism, showing $R_{!}$ to be injective.
-
•
Item 2$\implies $Item 1: Conversely, suppose that $R_{!}$ is injective, consider the diagram
and suppose that $R\mathbin {\diamond }S=R\mathbin {\diamond }T$. Note that, since $R_{!}$ is injective, given a diagram of the form if $R_{!}(U)=R\mathbin {\diamond }U=R\mathbin {\diamond }V=R_{!}(V)$, then $U=V$. In particular, for each $x\in X$, we may consider the diagram where we have $R\mathbin {\diamond }S\mathbin {\diamond }[x]=R\mathbin {\diamond }T\mathbin {\diamond }[x]$, implying that we have
\[ S(x)=S\mathbin {\diamond }[x]=T\mathbin {\diamond }[x]=T(x) \]
for each $x\in X$. Thus $S=T$ and $R$ is a monomorphism.
A more abstract proof can also be given, following [Yuan, Mono's and epi's in the category Rel?]:
-
•
Proposition 8.5.10.1.2$\implies $Proposition 8.5.10.1.3: Assume that $R$ is a monomorphism.
-
•
We first notice that the functor $\mathrm{Rel}(\mathrm{pt},-)\colon \mathrm{Rel}\to \mathsf{Sets}$ maps $R$ to $R_{!}$ by Remark 8.7.1.1.3.
-
•
Since $\mathrm{Rel}(\mathrm{pt},-)$ preserves all limits by 
, of , it follows by , of that $\mathrm{Rel}(\mathrm{pt},-)$ also preserves monomorphisms.
-
•
Since $R$ is a monomorphism and $\mathrm{Rel}(\mathrm{pt},-)$ maps $R$ to $R_{!}$, it follows that $R_{!}$ is also a monomorphism.
-
•
Since the monomorphisms in $\mathsf{Sets}$ are precisely the injections (, of ), it follows that $R_{!}$ is injective.
-
•
Proposition 8.5.10.1.3$\implies $Proposition 8.5.10.1.2: Assume that $R_{!}$ is injective.
-
•
We first notice that the functor $\mathrm{Rel}(\mathrm{pt},-)\colon \mathrm{Rel}\to \mathsf{Sets}$ maps $R$ to $R_{!}$ by Remark 8.7.1.1.3.
-
•
Since the monomorphisms in $\mathsf{Sets}$ are precisely the injections (, of ), it follows that $R_{!}$ is a monomorphism.
-
•
Since $\mathrm{Rel}(\mathrm{pt},-)$ is faithful, it follows by , of that $\mathrm{Rel}(\mathrm{pt},-)$ reflects monomorphisms.
-
•
Since $R_{!}$ is a monomorphism and $\mathrm{Rel}(\mathrm{pt},-)$ maps $R$ to $R_{!}$, it follows that $R$ is also a monomorphism.
We claim that Item 2 and Item 6 are equivalent:
-
•
Item 2$\implies $Item 6: We proceed in a few steps:
-
•
Let $U,V\in \mathcal{P}(A)$ such that $R_{!}(U)\subset R_{!}(V)$, assume $R_{!}$ to be injective, and consider the set $U\cup V$.
-
•
Since $R_{!}(U)\subset R_{!}(V)$, we have
\begin{align*} R_{!}(U\cup V) & = R_{!}(U)\cup R_{!}(V)\\ & = R_{!}(V), \end{align*}
where we have used Item 13 of Proposition 8.7.1.1.4 for the first equality.
-
•
Since $R_{!}$ is injective, this implies $U\cup V=V$.
-
•
Thus $U\subset V$, as we wished to show.
-
•
Item 2$\implies $Item 6: We proceed in a few steps:
-
•
Suppose Item 6 holds, and let $U,V\in \mathcal{P}(A)$ such that $R_{!}(U)=R_{!}(V)$.
-
•
Since $R_{!}(U)=R_{!}(V)$, we have $R_{!}(U)\subset R_{!}(V)$ and $R_{!}(V)\subset R_{!}(U)$.
-
•
By assumption, this implies $U\subset V$ and $V\subset U$.
-
•
Thus $U=V$, showing $R_{!}$ to be injective.
By , a right adjoint functor between posets, such as $R_{-1}$, is surjective iff its left adjoint, in this case $R_{!}$, is full.
By Item 5 of Proposition 8.7.1.1.5, $R^{-1}$ is surjective iff $R^{\dagger }_{!}$ is surjective. By Item 7 of Proposition 8.5.11.1.2, this happens iff $R^{\dagger }$ is an epimorphism. By the self-duality of $\mathsf{Rel}$ (Proposition 8.5.1.1.1) coupled with , this happens iff $R$ is a monomorphism.
This follows from the fact that $\mathcal{P}(B)$ is locally posetal.
This follows from the fact that $\mathcal{P}(A)$ is locally posetal.
This follows from the fact that $\mathcal{P}(A)$ is locally posetal.
This follows from the fact that $\mathcal{P}(B)$ is locally posetal.
We claim that Item 6 and Item 12 are equivalent:
-
•
Item 6$\implies $Item 12: Let $U,V\in \mathcal{P}(A)$ and consider the diagram
By Remark 8.7.1.1.3, we have
\begin{align*} R_{!}(U) & = R\mathbin {\diamond }U,\\ R_{!}(V) & = R\mathbin {\diamond }V. \end{align*}
Now, if $R\mathbin {\diamond }U\subset R\mathbin {\diamond }V$, then $R_{!}(U)\subset R_{!}(V)$. By assumption, we then have $U\subset V$.
-
•
Item 12$\implies $Item 6: Consider the diagram
and suppose that $R\mathbin {\diamond }S\subset R\mathbin {\diamond }T$. Note that, by assumption, given a diagram of the form if $R_{!}(U)=R\mathbin {\diamond }U\subset R\mathbin {\diamond }V=R_{!}(V)$, then $U\subset V$. In particular, for each $x\in X$, we may consider the diagram for which we have $R\mathbin {\diamond }S\mathbin {\diamond }[x]\subset R\mathbin {\diamond }T\mathbin {\diamond }[x]$, implying that we have
\[ S(x)=S\mathbin {\diamond }[x]\subset T\mathbin {\diamond }[x]=T(x) \]
for each $x\in X$, implying $S\subset T$.
This finishes the proof.
We defer this proof to Corollary 8.5.10.1.4.
We defer this proof to Corollary 8.5.10.1.4.
We defer this proof to Corollary 8.5.10.1.5.
Let $R\colon A\mathrel {\rightarrow \kern -9.5pt\mathrlap {|}\kern 6pt}B$ be a relation. The following conditions are equivalent:
-
1.
The relation $R$ is a monomorphism in $\mathsf{Rel}$.
-
2.
For each $a\in A$ and each $U\in \mathcal{P}(A)$, if $R(a)\subset R(U)$, then $a\in U$.
-
3.
For each $a\in A$, there exists some $b\in B$ such that $R^{-1}(b)=\left\{ a\right\} $.
We will prove this by showing:
We proceed in a few steps:
-
•
If $R$ is a monomorphism, then, by Item 2 of Proposition 8.5.10.1.2, the functor
\[ R_{!}\colon (\mathcal{P}(A),\subset )\to (\mathcal{P}(B),\subset ) \]
is full.
-
•
As a result, given $a\in A$ and $U\in \mathcal{P}(A)$ such that $R(a)\subset R(U)$, it follows that $\left\{ a\right\} \subset U$.
-
•
Thus, we have $a\in U$.
We proceed in a few steps:
-
•
Let $a\in A$ and consider the subset $U=A\setminus \left\{ a\right\} $.
-
•
Since $a\not\in U$, we have $R(a)\centernot {\subset }R(U)$ by the contrapositve of Item 2.
-
•
As a result, there must exist some $b\in R(a)$ with $b\not\in R(U)$.
-
•
In particular, we have $a\in R^{-1}(b)$.
-
•
Moreover, the condition $b\not\in R(U)=R(A\setminus \left\{ a\right\} )$ means that, if $a'\in A\setminus \left\{ a\right\} $, then $a'\not\in R^{-1}(b)$.
-
•
Thus $R^{-1}(b)=\left\{ a\right\} $.
We proceed in a few steps:
-
•
By the equivalence between Item 1 and Item 6 of Proposition 8.5.10.1.2, to show that $R$ is a monomorphism it suffices to prove that, for each $U,V\in \mathcal{P}(A)$, if $R(U)\subset R(V)$, then $U\subset V$.
-
•
So let $u\in U$ and assume $R(U)\subset R(V)$.
-
•
By assumption, there exists some $b\in B$ with $R^{-1}(b)=\left\{ u\right\} $.
-
•
In particular, $b\in R(U)$.
-
•
Since $R(U)\subset R(V)$, we also have $b\in R(V)$.
-
•
Thus, there exists some $v\in V$ with $b\in R(v)$.
-
•
However, $R^{-1}(b)=\left\{ u\right\} $, so we must in fact have $v=u$.
-
•
Therefore $u\in V$, showing that $U\subset V$.
This finishes the proof.
Item 1, Item 13, Item 14, and Item 14 of Proposition 8.5.10.1.2 are indeed equivalent.
We claim that Item 3 of Proposition 8.5.10.1.3 is equivalent to Item 13 of Proposition 8.5.10.1.2:
-
•
Item 3 of Proposition 8.5.10.1.3$\implies $Item 13: By assumption, given $a\in A$, there exists some $b\in B$ such that $R^{-1}(b)=\left\{ a\right\} $. Invoking the axiom of choice, we may pick one such $b$ for each $a\in A$, giving us our desired function $f\colon A\to B$. All the requirements listed in Item 13 of Proposition 8.5.10.1.2 then follow by construction.
-
•
Item 13$\implies $Item 3 of Proposition 8.5.10.1.3: Given $a\in A$, we may pick $b=f(a)$, in which case $R^{-1}(f(a))$ will be equal to $\left\{ a\right\} $ by assumption.
By Proposition 8.5.10.1.3, Item 3 of Proposition 8.5.10.1.3 is equivalent to Item 1 of Proposition 8.5.10.1.3. Since Item 1 of Proposition 8.5.10.1.3 is exactly the same condition as Item 1 of Proposition 8.5.10.1.2, the result follows.
Indeed, we have
\begin{align*} [R_{-1}\circ R_{!}](U) & \mathrel {\smash {\overset {\mathclap {\scriptscriptstyle \text{def}}}=}}R_{-1}(R_{!}(U))\\ & \mathrel {\smash {\overset {\mathclap {\scriptscriptstyle \text{def}}}=}}\left\{ a\in A\ \middle |\ R(a)\subset R(U)\right\} \end{align*}
for each $U\in \mathcal{P}(A)$. As a result, the condition $R_{-1}\circ R_{!}=\operatorname {\mathrm{id}}_{\mathcal{P}(A)}$ becomes
\[ \left\{ a\in A\ \middle |\ R(a)\subset R(U)\right\} =U, \]
which holds precisely when Item 2 of Proposition 8.5.10.1.3 does. By Proposition 8.5.10.1.3, that in turn holds precisely if Item 1 of Proposition 8.5.10.1.3 holds. Since Item 1 of Proposition 8.5.10.1.3 is exactly the same condition as Item 1 of Proposition 8.5.10.1.2, the result follows.
Item 1 and Item 15 of Proposition 8.5.10.1.2 are indeed equivalent.
We proceed by taking a specific choice of subset $U$:
-
•
Let $a$ be an arbitrary element of $A$. By our assumption, the condition $R^{-1}(R_{*}(U))=U$ must hold for the singleton set $U=\left\{ a\right\} $.
-
•
From $R^{-1}(R_{*}(\left\{ a\right\} ))=\left\{ a\right\} $, it follows that $a\in R^{-1}(R_{*}(\left\{ a\right\} ))$.
-
•
This means there must exist some $b\in R(a)$ such that $R^{-1}(b)\subset \left\{ a\right\} $.
-
•
The condition $b\in R(a)$ implies that $a\in R^{-1}(b)$. Therefore, $R^{-1}(b)$ is a non-empty subset of $\left\{ a\right\} $.
-
•
The only non-empty subset of $\left\{ a\right\} $ is $\left\{ a\right\} $ itself.
-
•
Thus, we must have $R^{-1}(b)=\left\{ a\right\} $.
By Item 3 of Proposition 8.5.10.1.3, it then follows that $R$ is a monomorphism.
By Item 3 of Proposition 8.5.10.1.3, for each $a\in A$, there exists some $b\in B$ such that $R^{-1}(b)=\left\{ a\right\} $. We need to show that $R^{-1}(R_{*}(U))=U$ for any $U\in \mathcal{P}(A)$, which requires proving two set inclusions.
-
•
$R^{-1}(R_{*}(U))\subset U$: We proceed in a few steps:
-
•
Let $a\in R^{-1}(R_{*}(U))$.
-
•
By definition, there exists some $b\in R(a)$ such that $R^{-1}(b)\subset U$.
-
•
Since $b\in R(a)$ implies $a\in R^{-1}(b)$, it follows immediately that $a\in U$.
-
•
Thus, $R^{-1}(R_{*}(U))\subset U$.
-
•
$U\subset R^{-1}(R_{*}(U))$: Let $a\in U$. By assumption, there exists an element $b\in B$ such that $R^{-1}(b)=\left\{ a\right\} $. Thus $R^{-1}(b)\subset U$, so $a\in R^{-1}(R_{*}(U))$.
Combining both inclusions gives $R^{-1}(R_{*}(U))=U$.
ゴ
ゴ
ゴ
The following conditions are equivalent and imply $R$ is a monomorphism, but the converse may fail. Thus, they are not equivalent to $R$ being a monomorphism:
-
1.
The relation $R$ is total and injective.
-
2.
The diagram
commutes. In other words, we have
\[ R^{-1}(R(a))=\left\{ a\right\} \]
for each $a\in A$.
-
3.
We have
In other words, we have
\[ U=\underbrace{\left\{ a\in A\ \middle |\ R(a)\cap R(U)\neq \text{Ø}\right\} }_{=R^{-1}(R_{!}(U))} \]
for each $U\in \mathcal{P}(A)$.
-
4.
We have
In other words, we have
\[ U=\underbrace{\left\{ a\in A\ \middle |\ R^{-1}(R(a))\subset U\right\} }_{=R_{-1}(R_{*}(U))} \]
for each $U\in \mathcal{P}(A)$.
Moreover, if $R$ is a monomorphism, then it satisfies the following condition, but the converse may fail:
- (★)
For each $a,a'\in A$, if $R(a)=R(a')$, then $a=a'$.
ゴ
ゴ
ゴ
We proceed by showing:
Suppose that $R$ is total and injective. Given $a\in A$, we wish to show that $R^{-1}(R(a))=\left\{ a\right\} $.
-
•
Let $x\in R^{-1}(R(a))$. By definition, this means $R(x)\cap R(a)\neq \text{Ø}$.
-
•
Since the image sets are pairwise disjoint, this can only be true if $x=a$.
-
•
Therefore, $R^{-1}(R(a))\subset \left\{ a\right\} $.
-
•
Since $R$ is total, $R(a)$ is non-empty.
-
•
Thus $R(a)\cap R(a)\neq \text{Ø}$, which implies $a\in R^{-1}(R(a))$.
-
•
Therefore, $\left\{ a\right\} \subset R^{-1}(R(a))$.
Combining both inclusions, we have $R^{-1}(R(a))=\left\{ a\right\} $.
By definition,
\[ R^{-1}(R(a))=\left\{ x\in A \mid R(x)\cap R(a)\neq \text{Ø}\right\} . \]
The condition $R^{-1}(R(a))=\left\{ a\right\} $ implies two facts:
-
•
Totality. The element $a$ must belong to the set $\left\{ x\in A \mid R(x)\cap R(a)\neq \text{Ø}\right\} $. For this to be true, the condition must hold for $x=a$, so $R(a)\cap R(a)\neq \text{Ø}$. This is equivalent to $R(a)\neq \text{Ø}$. Since this must hold for all $a\in A$, the relation $R$ is total.
-
•
Injectivity. Any element $x\in A$ such that $x\neq a$ must not belong to the set. This means that for any $x\neq a$, we must have $R(x)\cap R(a)=\text{Ø}$. This means the image sets of distinct elements of $A$ are pairwise disjoint.
Thus, $R$ is total and injective.
We have
\begin{align*} R^{-1}(R_{*}(U)) & = \left\{ a\in A\ \middle |\ R^{-1}(R(a))\subset U\right\} \\ & = \left\{ a\in A\ \middle |\ \left\{ a\right\} \subset U\right\} \\ & = U. \end{align*}
Let $a\in A$.
-
•
First, let $U=\left\{ a\right\} $. By assumption, we have
\[ \left\{ a\right\} =\left\{ a'\in A\ \middle |\ R^{-1}(R(a'))\subset \left\{ a\right\} \right\} . \]
Since $a$ is in the set on the left-hand side, it must also be in the set on the right-hand side. Thus $R^{-1}(R(a'))\subset \left\{ a\right\} $ must be true.
-
•
Next, consider the complement $U=A\setminus \left\{ a\right\} $. By assumption, we have
\[ A\setminus \left\{ a\right\} =\left\{ a'\in A\ \middle |\ R^{-1}(R(a'))\subset A\setminus \left\{ a\right\} \right\} \]
Since $a$ is not in the set on the left-hand side, it cannot be in the set on the right-hand side. Thus $R^{-1}(R(a))\centernot {\subset }A\setminus \left\{ a\right\} $.
-
•
The statement $R^{-1}(R(a))\centernot {\subset }A\setminus \left\{ a\right\} $ implies that there exists an element $x\in R^{-1}(R(a))$ such that $x\not\in A\setminus \left\{ a\right\} $. The only such element is $a$, so we must have $a\in R^{-1}(R(a))$.
-
•
Combining these two results, namely $R^{-1}(R(a))\subset \left\{ a\right\} $ and $a\in R^{-1}(R(a))$, we conclude that $R^{-1}(R(a))=\left\{ a\right\} $, as we wished to show.
Assume that $R$ is total and injective. Let $S(U)\mathrel {\smash {\overset {\mathclap {\scriptscriptstyle \text{def}}}=}}\left\{ a\in A \mid R(a)\cap R(U)\neq \text{Ø}\right\} $. We need to show that $U = S(U)$ for any $U \in \mathcal{P}(A)$ by proving double inclusion.
-
•
$U\subset S(U)$: Let $u\in U$.
-
•
Since $R$ is total, we have $R(u)\neq \text{Ø}$.
-
•
By definition, $R(U)=\bigcup _{x\in U}R(x)$, so $R(u)\subset R(U)$.
-
•
Therefore, $R(u)\cap R(U)=R(u)$.
-
•
Since $R(u)\neq \text{Ø}$, we have $R(u)\cap R(U)\neq \text{Ø}$.
-
•
By the definition of $S(U)$, it follows that $u\in S(U)$.
-
•
$S(U)\subset U$: Let $a\in S(U)$.
-
•
By assumption, $R(a)\cap R(U)\neq \text{Ø}$.
-
•
This means $R(a)\cap \bigcup _{u\in U}R(u)\neq \text{Ø}$.
-
•
Using the distributivity of intersection over union (Chapter 4: Constructions With Sets, Item 8 of Proposition 4.3.6.1.2), this is equivalent to
\[ \bigcup _{u\in U}(R(a)\cap R(u))\neq \text{Ø}. \]
-
•
For this union of sets to be non-empty, at least one of the sets in the union must be non-empty. Thus, there must exist some $u\in U$ such that $R(a)\cap R(u)\neq \text{Ø}$.
-
•
Since $R$ is injective, the images of distinct elements are disjoint. Thus, for the intersection $R(a)\cap R(u)$ to be non-empty, we must therefore have $a=u$.
-
•
Since $u\in U$, it follows that $a\in U$.
As both inclusions hold, we conclude that $U=S(U)$.
Assume that for every $U\in \mathcal{P}(A)$, we have $U=\left\{ a\in A\ \middle |\ R(a)\cap R(U)\neq \text{Ø}\right\} $. We must show that $R$ is both total and injective.
-
•
Totality: Let $a\in A$. We must show that $R(a)\neq \text{Ø}$.
-
•
Consider the singleton set $U=\left\{ a\right\} $.
-
•
By assumption, $U=\left\{ x\in A\ \middle |\ R(x)\cap R(U)\neq \text{Ø}\right\} $.
-
•
Since $a\in U$, we must have $R(a)\cap R(U)\neq \text{Ø}$.
-
•
Substituting $U=\left\{ a\right\} $, we get $R(a)\cap R(\left\{ a\right\} )\neq \text{Ø}$.
-
•
Since $R(\left\{ a\right\} )=R(a)$, this simplifies to $R(a)\cap R(a)=R(a)\neq \text{Ø}$.
-
•
Thus $R(a)\neq \text{Ø}$ for all $a\in A$, showing $R$ to be total.
-
•
Injectivity: Let $a,a'\in A$ such that $a\neq a'$. We must show that $R(a)\cap R(a')=\text{Ø}$.
-
•
Consider the singleton set $U=\left\{ a\right\} $.
-
•
By assumption, $U=\left\{ x\in A\ \middle |\ R(x)\cap R(U)\neq \text{Ø}\right\} $.
-
•
Since $a\neq a'$, we have $a'\not\in U$.
-
•
Therefore, $a'$ cannot satisfy the membership condition for $U$. This means $R(a')\cap R(U)=\text{Ø}$.
-
•
Substituting $U=\left\{ a\right\} $, we get $R(a')\cap R(\left\{ a\right\} )=\text{Ø}$, which simplifies to $R(a')\cap R(a)=\text{Ø}$.
-
•
As this holds for any pair of distinct elements, the relation $R$ is injective.
This completes the proof.
Step 7: $R$ Is a Monomorphism $\centernot {\implies }$
Item 1
Step 8:
Item 1$\implies $ $R$ Is a Monomorphism
-
•
Since $R$ is total and $a\in A$, there exists some $b\in B$ such that $a\sim _{R}b$.
-
•
In this case, we have $x\sim _{R\mathbin {\diamond }S}b$, and since $R\mathbin {\diamond }S=R\mathbin {\diamond }T$, we have also $x\sim _{R\mathbin {\diamond }T}b$.
-
•
Thus there must exist some $a'\in A$ such that $x\sim _{T}a'$ and $a'\sim _{R}b$.
-
•
However, since $a\sim _{R}b$ and $a'\sim _{R}b$, we must have $a=a'$ since $R$ is injective.
-
•
Thus $x\sim _{T}a$ as well.
-
•
A similar argument shows that if $x\sim _{T}a$, then $x\sim _{S}a$.
-
•
Thus $S=T$, showing $R$ to be a monomorphism.
This finishes the proof.
Step 9: Proof of $(\star )$
This follows from Item 2 of Proposition 8.5.10.1.2.
Step 10: Counterexample to the converse of $(\star )$
Let $A=\left\{ a_{1},a_{2},a_{3}\right\} $, let $B=\left\{ b_{1},b_{2}\right\} $, and let $R\colon A\mathrel {\rightarrow \kern -9.5pt\mathrlap {|}\kern 6pt}B$ be the relation defined by
\begin{align*} R(a_{1}) & = \left\{ b_{1}\right\} ,\\ R(a_{2}) & = \left\{ b_{2}\right\} ,\\ R(a_{3}) & = \left\{ b_{1},b_{2}\right\} . \end{align*}
Since $R(a_{1})$, $R(a_{2})$, and $R(a_{3})$ are all distinct, $R$ satisfies the condition in $(\star )$.
Taking $U=\left\{ a_{1},a_{2}\right\} $ and $V=\left\{ a_{3}\right\} $, however, shows that $R(U)=R(V)$ holds while $U\neq V$, so $R$ can’t be a monomorphism.
Every 1-morphism in $\boldsymbol {\mathsf{Rel}}$ is representably faithful.
A relation $R\colon A\mathrel {\rightarrow \kern -9.5pt\mathrlap {|}\kern 6pt}B$ will be representably faithful in $\boldsymbol {\mathsf{Rel}}$ iff, for each $X\in \operatorname {\mathrm{Obj}}(\boldsymbol {\mathsf{Rel}})$, the functor
\[ R_{*}\colon \mathbf{Rel}(X,A)\to \mathbf{Rel}(X,B) \]
given by postcomposition by $R$ is faithful. This happens iff the morphism
\[ R_{*|S,T}\colon \operatorname {\mathrm{Hom}}_{\mathbf{Rel}(X,A)}(S,T)\to \operatorname {\mathrm{Hom}}_{\mathbf{Rel}(X,B)}(R\mathbin {\diamond }S,R\mathbin {\diamond }T) \]
is injective for each $S,T\in \operatorname {\mathrm{Obj}}(\mathbf{Rel}(X,A))$.
However, since $\boldsymbol {\mathsf{Rel}}$ is locally posetal, the Hom-set $\operatorname {\mathrm{Hom}}_{\mathbf{Rel}(X,A)}(S,T)$ is either empty or a singleton. As a result, the map $R_{*|S,T}$ will necessarily be injective in either of these cases.
Let $R\colon A\mathrel {\rightarrow \kern -9.5pt\mathrlap {|}\kern 6pt}B$ be a relation. The following conditions are equivalent:
-
1.
The morphism $R\colon A\mathrel {\rightarrow \kern -9.5pt\mathrlap {|}\kern 6pt}B$ is a monomorphism in $\mathsf{Rel}$.
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2.
The 1-morphism $R\colon A\mathrel {\rightarrow \kern -9.5pt\mathrlap {|}\kern 6pt}B$ is representably full in $\boldsymbol {\mathsf{Rel}}$.
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3.
The 1-morphism $R\colon A\mathrel {\rightarrow \kern -9.5pt\mathrlap {|}\kern 6pt}B$ is representably fully faithful in $\boldsymbol {\mathsf{Rel}}$.
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4.
The 1-morphism $R\colon A\mathrel {\rightarrow \kern -9.5pt\mathrlap {|}\kern 6pt}B$ is pseudomonic in $\boldsymbol {\mathsf{Rel}}$.
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5.
The 1-morphism $R\colon A\mathrel {\rightarrow \kern -9.5pt\mathrlap {|}\kern 6pt}B$ is representably essentially injective in $\boldsymbol {\mathsf{Rel}}$.
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6.
The 1-morphism $R\colon A\mathrel {\rightarrow \kern -9.5pt\mathrlap {|}\kern 6pt}B$ is representably conservative in $\boldsymbol {\mathsf{Rel}}$.
We will prove this by showing:
The condition that $R$ is representably full corresponds precisely to Item 12 of Proposition 8.5.10.1.2, so this follows by Proposition 8.5.10.1.2.
This follows from Step 1 and Proposition 8.5.10.1.8.
Since $\boldsymbol {\mathsf{Rel}}$ is locally posetal, the conditions in Item 4, Item 5, and Item 6 all collapse to the one of Item 3.
