clwwlknonel

Description: Characterization of a word over the set of vertices representing a closed walk on vertex X of (nonzero) length N in a graph G . This theorem would not hold for N = 0 if W = X = (/) . (Contributed by Alexander van der Vekens, 20-Sep-2018) (Revised by AV, 28-May-2021) (Revised by AV, 24-Mar-2022)

	Ref	Expression
Hypotheses	clwwlknonel.v	$⊢ V = Vtx (G)$
	clwwlknonel.e	$⊢ E = Edg (G)$
Assertion	clwwlknonel	$⊢ N \neq 0 \to (W \in (X ClWWalksNOn (G) N) \leftrightarrow ((W \in Word V \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E) \land \|W\| = N \land W (0) = X))$

Proof

Step	Hyp	Ref	Expression
1		clwwlknonel.v	$⊢ V = Vtx (G)$
2		clwwlknonel.e	$⊢ E = Edg (G)$
3	1 2	isclwwlk	$⊢ W \in ClWWalks (G) \leftrightarrow ((W \in Word V \land W \neq \emptyset) \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E)$
4		simpl	$⊢ (\|W\| = N \land W = \emptyset) \to \|W\| = N$
5		fveq2	$⊢ W = \emptyset \to \|W\| = \|\emptyset\|$
6		hash0	$⊢ \|\emptyset\| = 0$
7	5 6	eqtrdi	$⊢ W = \emptyset \to \|W\| = 0$
8	7	adantl	$⊢ (\|W\| = N \land W = \emptyset) \to \|W\| = 0$
9	4 8	eqtr3d	$⊢ (\|W\| = N \land W = \emptyset) \to N = 0$
10	9	ex	$⊢ \|W\| = N \to (W = \emptyset \to N = 0)$
11	10	necon3d	$⊢ \|W\| = N \to (N \neq 0 \to W \neq \emptyset)$
12	11	impcom	$⊢ (N \neq 0 \land \|W\| = N) \to W \neq \emptyset$
13	12	biantrud	$⊢ (N \neq 0 \land \|W\| = N) \to (W \in Word V \leftrightarrow (W \in Word V \land W \neq \emptyset))$
14	13	bicomd	$⊢ (N \neq 0 \land \|W\| = N) \to ((W \in Word V \land W \neq \emptyset) \leftrightarrow W \in Word V)$
15	14	3anbi1d	$⊢ (N \neq 0 \land \|W\| = N) \to (((W \in Word V \land W \neq \emptyset) \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E) \leftrightarrow (W \in Word V \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E))$
16	3 15	syl5bb	$⊢ (N \neq 0 \land \|W\| = N) \to (W \in ClWWalks (G) \leftrightarrow (W \in Word V \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E))$
17	16	a1d	$⊢ (N \neq 0 \land \|W\| = N) \to (W (0) = X \to (W \in ClWWalks (G) \leftrightarrow (W \in Word V \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E)))$
18	17	expimpd	$⊢ N \neq 0 \to ((\|W\| = N \land W (0) = X) \to (W \in ClWWalks (G) \leftrightarrow (W \in Word V \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E)))$
19	18	pm5.32rd	$⊢ N \neq 0 \to ((W \in ClWWalks (G) \land (\|W\| = N \land W (0) = X)) \leftrightarrow ((W \in Word V \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E) \land (\|W\| = N \land W (0) = X)))$
20		isclwwlknon	$⊢ W \in (X ClWWalksNOn (G) N) \leftrightarrow (W \in (N ClWWalksN G) \land W (0) = X)$
21		isclwwlkn	$⊢ W \in (N ClWWalksN G) \leftrightarrow (W \in ClWWalks (G) \land \|W\| = N)$
22	21	anbi1i	$⊢ (W \in (N ClWWalksN G) \land W (0) = X) \leftrightarrow ((W \in ClWWalks (G) \land \|W\| = N) \land W (0) = X)$
23		anass	$⊢ ((W \in ClWWalks (G) \land \|W\| = N) \land W (0) = X) \leftrightarrow (W \in ClWWalks (G) \land (\|W\| = N \land W (0) = X))$
24	20 22 23	3bitri	$⊢ W \in (X ClWWalksNOn (G) N) \leftrightarrow (W \in ClWWalks (G) \land (\|W\| = N \land W (0) = X))$
25		3anass	$⊢ ((W \in Word V \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E) \land \|W\| = N \land W (0) = X) \leftrightarrow ((W \in Word V \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E) \land (\|W\| = N \land W (0) = X))$
26	19 24 25	3bitr4g	$⊢ N \neq 0 \to (W \in (X ClWWalksNOn (G) N) \leftrightarrow ((W \in Word V \land \forall i \in (0 ..^\|W\| - 1) \{W (i), W (i + 1)\} \in E \land \{lastS (W), W (0)\} \in E) \land \|W\| = N \land W (0) = X))$

Metamath Proof Explorer

Theorem clwwlknonel

Proof