Metamath Proof Explorer

Theorem upgredg

Description: For each edge in a pseudograph, there are two vertices which are connected by this edge. (Contributed by AV, 4-Nov-2020) (Proof shortened by AV, 26-Nov-2021)

		Ref	Expression
	Hypotheses	upgredg.v	$⊢ V = Vtx (G)$
		upgredg.e	$⊢ E = Edg (G)$
	Assertion	upgredg	$⊢ (G \in UPGraph \land C \in E) \to \exists a \in V \exists b \in V C = \{a, b\}$

Proof

Step	Hyp	Ref	Expression
1		upgredg.v	$⊢ V = Vtx (G)$
2		upgredg.e	$⊢ E = Edg (G)$
3		edgval	$⊢ Edg (G) = ran iEdg (G)$
4	3	a1i	$⊢ G \in UPGraph \to Edg (G) = ran iEdg (G)$
5	2 4	syl5eq	$⊢ G \in UPGraph \to E = ran iEdg (G)$
6	5	eleq2d	$⊢ G \in UPGraph \to (C \in E \leftrightarrow C \in ran iEdg (G))$
7		eqid	$⊢ iEdg (G) = iEdg (G)$
8	1 7	upgrf	$⊢ G \in UPGraph \to iEdg (G) : dom iEdg (G) ⟶ \{x \in (𝒫 V ∖ \{\emptyset\}) \| \|x\| \leq 2\}$
9	8	frnd	$⊢ G \in UPGraph \to ran iEdg (G) \subseteq \{x \in (𝒫 V ∖ \{\emptyset\}) \| \|x\| \leq 2\}$
10	9	sseld	$⊢ G \in UPGraph \to (C \in ran iEdg (G) \to C \in \{x \in (𝒫 V ∖ \{\emptyset\}) \| \|x\| \leq 2\})$
11	6 10	sylbid	$⊢ G \in UPGraph \to (C \in E \to C \in \{x \in (𝒫 V ∖ \{\emptyset\}) \| \|x\| \leq 2\})$
12	11	imp	$⊢ (G \in UPGraph \land C \in E) \to C \in \{x \in (𝒫 V ∖ \{\emptyset\}) \| \|x\| \leq 2\}$
13		fveq2	$⊢ x = C \to \|x\| = \|C\|$
14	13	breq1d	$⊢ x = C \to (\|x\| \leq 2 \leftrightarrow \|C\| \leq 2)$
15	14	elrab	$⊢ C \in \{x \in (𝒫 V ∖ \{\emptyset\}) \| \|x\| \leq 2\} \leftrightarrow (C \in (𝒫 V ∖ \{\emptyset\}) \land \|C\| \leq 2)$
16		hashle2prv	$⊢ C \in (𝒫 V ∖ \{\emptyset\}) \to (\|C\| \leq 2 \leftrightarrow \exists a \in V \exists b \in V C = \{a, b\})$
17	16	biimpa	$⊢ (C \in (𝒫 V ∖ \{\emptyset\}) \land \|C\| \leq 2) \to \exists a \in V \exists b \in V C = \{a, b\}$
18	15 17	sylbi	$⊢ C \in \{x \in (𝒫 V ∖ \{\emptyset\}) \| \|x\| \leq 2\} \to \exists a \in V \exists b \in V C = \{a, b\}$
19	12 18	syl	$⊢ (G \in UPGraph \land C \in E) \to \exists a \in V \exists b \in V C = \{a, b\}$