Metamath Proof Explorer

Theorem loopclwwlkn1b

Description: The singleton word consisting of a vertex V represents a closed walk of length 1 iff there is a loop at vertex V . (Contributed by AV, 11-Feb-2022)

		Ref	Expression
	Assertion	loopclwwlkn1b	$⊢ V \in Vtx (G) \to (\{V\} \in Edg (G) \leftrightarrow ⟨“ V ”⟩ \in (1 ClWWalksN G))$

Proof

Step	Hyp	Ref	Expression
1		clwwlkn1	$⊢ ⟨“ V ”⟩ \in (1 ClWWalksN G) \leftrightarrow (\|⟨“ V ”⟩\| = 1 \land ⟨“ V ”⟩ \in Word Vtx (G) \land \{⟨“ V ”⟩ (0)\} \in Edg (G))$
2		s1fv	$⊢ V \in Vtx (G) \to ⟨“ V ”⟩ (0) = V$
3	2	sneqd	$⊢ V \in Vtx (G) \to \{⟨“ V ”⟩ (0)\} = \{V\}$
4	3	eleq1d	$⊢ V \in Vtx (G) \to (\{⟨“ V ”⟩ (0)\} \in Edg (G) \leftrightarrow \{V\} \in Edg (G))$
5	4	biimpcd	$⊢ \{⟨“ V ”⟩ (0)\} \in Edg (G) \to (V \in Vtx (G) \to \{V\} \in Edg (G))$
6	5	3ad2ant3	$⊢ (\|⟨“ V ”⟩\| = 1 \land ⟨“ V ”⟩ \in Word Vtx (G) \land \{⟨“ V ”⟩ (0)\} \in Edg (G)) \to (V \in Vtx (G) \to \{V\} \in Edg (G))$
7	6	com12	$⊢ V \in Vtx (G) \to ((\|⟨“ V ”⟩\| = 1 \land ⟨“ V ”⟩ \in Word Vtx (G) \land \{⟨“ V ”⟩ (0)\} \in Edg (G)) \to \{V\} \in Edg (G))$
8		s1len	$⊢ \|⟨“ V ”⟩\| = 1$
9	8	a1i	$⊢ (V \in Vtx (G) \land \{V\} \in Edg (G)) \to \|⟨“ V ”⟩\| = 1$
10		s1cl	$⊢ V \in Vtx (G) \to ⟨“ V ”⟩ \in Word Vtx (G)$
11	10	adantr	$⊢ (V \in Vtx (G) \land \{V\} \in Edg (G)) \to ⟨“ V ”⟩ \in Word Vtx (G)$
12	2	eqcomd	$⊢ V \in Vtx (G) \to V = ⟨“ V ”⟩ (0)$
13	12	sneqd	$⊢ V \in Vtx (G) \to \{V\} = \{⟨“ V ”⟩ (0)\}$
14	13	eleq1d	$⊢ V \in Vtx (G) \to (\{V\} \in Edg (G) \leftrightarrow \{⟨“ V ”⟩ (0)\} \in Edg (G))$
15	14	biimpa	$⊢ (V \in Vtx (G) \land \{V\} \in Edg (G)) \to \{⟨“ V ”⟩ (0)\} \in Edg (G)$
16	9 11 15	3jca	$⊢ (V \in Vtx (G) \land \{V\} \in Edg (G)) \to (\|⟨“ V ”⟩\| = 1 \land ⟨“ V ”⟩ \in Word Vtx (G) \land \{⟨“ V ”⟩ (0)\} \in Edg (G))$
17	16	ex	$⊢ V \in Vtx (G) \to (\{V\} \in Edg (G) \to (\|⟨“ V ”⟩\| = 1 \land ⟨“ V ”⟩ \in Word Vtx (G) \land \{⟨“ V ”⟩ (0)\} \in Edg (G)))$
18	7 17	impbid	$⊢ V \in Vtx (G) \to ((\|⟨“ V ”⟩\| = 1 \land ⟨“ V ”⟩ \in Word Vtx (G) \land \{⟨“ V ”⟩ (0)\} \in Edg (G)) \leftrightarrow \{V\} \in Edg (G))$
19	1 18	syl5rbb	$⊢ V \in Vtx (G) \to (\{V\} \in Edg (G) \leftrightarrow ⟨“ V ”⟩ \in (1 ClWWalksN G))$