wlkiswwlks2

Description: A walk as word corresponds to the sequence of vertices in a walk in a simple pseudograph. (Contributed by Alexander van der Vekens, 21-Jul-2018) (Revised by AV, 10-Apr-2021)

		Ref	Expression
	Assertion	wlkiswwlks2	$⊢ G \in USHGraph \to (P \in WWalks (G) \to \exists f f Walks (G) P)$

Proof

Step	Hyp	Ref	Expression
1		eqid	$⊢ Vtx (G) = Vtx (G)$
2	1	wwlkbp	$⊢ P \in WWalks (G) \to (G \in V \land P \in Word Vtx (G))$
3		eqid	$⊢ Edg (G) = Edg (G)$
4	1 3	iswwlks	$⊢ P \in WWalks (G) \leftrightarrow (P \neq \emptyset \land P \in Word Vtx (G) \land \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G))$
5		ovex	$⊢ (0 ..^\|P\| - 1) \in V$
6		mptexg	$⊢ (0 ..^\|P\| - 1) \in V \to (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \in V$
7	5 6	mp1i	$⊢ ((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \to (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \in V$
8		simprr	$⊢ ((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \to G \in USHGraph$
9		simplr	$⊢ ((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \to P \in Word Vtx (G)$
10		hashge1	$⊢ (P \in Word Vtx (G) \land P \neq \emptyset) \to 1 \leq \|P\|$
11	10	ancoms	$⊢ (P \neq \emptyset \land P \in Word Vtx (G)) \to 1 \leq \|P\|$
12	11	adantr	$⊢ ((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \to 1 \leq \|P\|$
13	8 9 12	3jca	$⊢ ((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \to (G \in USHGraph \land P \in Word Vtx (G) \land 1 \leq \|P\|)$
14	13	adantr	$⊢ (((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \land f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))) \to (G \in USHGraph \land P \in Word Vtx (G) \land 1 \leq \|P\|)$
15		edgval	$⊢ Edg (G) = ran iEdg (G)$
16	15	a1i	$⊢ (((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \land f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))) \to Edg (G) = ran iEdg (G)$
17	16	eleq2d	$⊢ (((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \land f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))) \to (\{P (i), P (i + 1)\} \in Edg (G) \leftrightarrow \{P (i), P (i + 1)\} \in ran iEdg (G))$
18	17	ralbidv	$⊢ (((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \land f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))) \to (\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \leftrightarrow \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in ran iEdg (G))$
19	18	biimpd	$⊢ (((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \land f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))) \to (\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \to \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in ran iEdg (G))$
20		eqid	$⊢ (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))$
21		eqid	$⊢ iEdg (G) = iEdg (G)$
22	20 21	wlkiswwlks2lem6	$⊢ (G \in USHGraph \land P \in Word Vtx (G) \land 1 \leq \|P\|) \to (\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in ran iEdg (G) \to ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \in Word dom iEdg (G) \land P : (0 \dots \|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) iEdg (G) ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) (i)) = \{P (i), P (i + 1)\}))$
23	14 19 22	sylsyld	$⊢ (((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \land f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))) \to (\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \to ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \in Word dom iEdg (G) \land P : (0 \dots \|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) iEdg (G) ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) (i)) = \{P (i), P (i + 1)\}))$
24		eleq1	$⊢ f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \to (f \in Word dom iEdg (G) \leftrightarrow (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \in Word dom iEdg (G))$
25		fveq2	$⊢ f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \to \|f\| = \|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|$
26	25	oveq2d	$⊢ f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \to (0 \dots \|f\|) = (0 \dots \|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|)$
27	26	feq2d	$⊢ f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \to (P : (0 \dots \|f\|) ⟶ Vtx (G) \leftrightarrow P : (0 \dots \|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) ⟶ Vtx (G))$
28	25	oveq2d	$⊢ f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \to (0 ..^\|f\|) = (0 ..^\|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|)$
29		fveq1	$⊢ f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \to f (i) = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) (i)$
30	29	fveqeq2d	$⊢ f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \to (iEdg (G) (f (i)) = \{P (i), P (i + 1)\} \leftrightarrow iEdg (G) ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) (i)) = \{P (i), P (i + 1)\})$
31	28 30	raleqbidv	$⊢ f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \to (\forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\} \leftrightarrow \forall i \in (0 ..^\|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) iEdg (G) ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) (i)) = \{P (i), P (i + 1)\})$
32	24 27 31	3anbi123d	$⊢ f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \to ((f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\}) \leftrightarrow ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \in Word dom iEdg (G) \land P : (0 \dots \|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) iEdg (G) ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) (i)) = \{P (i), P (i + 1)\}))$
33	32	imbi2d	$⊢ f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \to ((\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \to (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\})) \leftrightarrow (\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \to ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \in Word dom iEdg (G) \land P : (0 \dots \|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) iEdg (G) ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) (i)) = \{P (i), P (i + 1)\})))$
34	33	adantl	$⊢ (((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \land f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))) \to ((\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \to (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\})) \leftrightarrow (\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \to ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) \in Word dom iEdg (G) \land P : (0 \dots \|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|(x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))\|) iEdg (G) ((x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\})) (i)) = \{P (i), P (i + 1)\})))$
35	23 34	mpbird	$⊢ (((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \land f = (x \in (0 ..^\|P\| - 1) ⟼ {iEdg (G)}^{-1} (\{P (x), P (x + 1)\}))) \to (\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \to (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\}))$
36	7 35	spcimedv	$⊢ ((P \neq \emptyset \land P \in Word Vtx (G)) \land ((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph)) \to (\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \to \exists f (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\}))$
37	36	ex	$⊢ (P \neq \emptyset \land P \in Word Vtx (G)) \to (((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph) \to (\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \to \exists f (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\})))$
38	37	com23	$⊢ (P \neq \emptyset \land P \in Word Vtx (G)) \to (\forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G) \to (((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph) \to \exists f (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\})))$
39	38	3impia	$⊢ (P \neq \emptyset \land P \in Word Vtx (G) \land \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G)) \to (((G \in V \land P \in Word Vtx (G)) \land G \in USHGraph) \to \exists f (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\}))$
40	39	expd	$⊢ (P \neq \emptyset \land P \in Word Vtx (G) \land \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G)) \to ((G \in V \land P \in Word Vtx (G)) \to (G \in USHGraph \to \exists f (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\})))$
41	40	impcom	$⊢ ((G \in V \land P \in Word Vtx (G)) \land (P \neq \emptyset \land P \in Word Vtx (G) \land \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G))) \to (G \in USHGraph \to \exists f (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\}))$
42	41	imp	$⊢ (((G \in V \land P \in Word Vtx (G)) \land (P \neq \emptyset \land P \in Word Vtx (G) \land \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G))) \land G \in USHGraph) \to \exists f (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\})$
43		uspgrupgr	$⊢ G \in USHGraph \to G \in UPGraph$
44	1 21	upgriswlk	$⊢ G \in UPGraph \to (f Walks (G) P \leftrightarrow (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\}))$
45	43 44	syl	$⊢ G \in USHGraph \to (f Walks (G) P \leftrightarrow (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\}))$
46	45	adantl	$⊢ (((G \in V \land P \in Word Vtx (G)) \land (P \neq \emptyset \land P \in Word Vtx (G) \land \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G))) \land G \in USHGraph) \to (f Walks (G) P \leftrightarrow (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\}))$
47	46	exbidv	$⊢ (((G \in V \land P \in Word Vtx (G)) \land (P \neq \emptyset \land P \in Word Vtx (G) \land \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G))) \land G \in USHGraph) \to (\exists f f Walks (G) P \leftrightarrow \exists f (f \in Word dom iEdg (G) \land P : (0 \dots \|f\|) ⟶ Vtx (G) \land \forall i \in (0 ..^\|f\|) iEdg (G) (f (i)) = \{P (i), P (i + 1)\}))$
48	42 47	mpbird	$⊢ (((G \in V \land P \in Word Vtx (G)) \land (P \neq \emptyset \land P \in Word Vtx (G) \land \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G))) \land G \in USHGraph) \to \exists f f Walks (G) P$
49	48	ex	$⊢ ((G \in V \land P \in Word Vtx (G)) \land (P \neq \emptyset \land P \in Word Vtx (G) \land \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G))) \to (G \in USHGraph \to \exists f f Walks (G) P)$
50	49	ex	$⊢ (G \in V \land P \in Word Vtx (G)) \to ((P \neq \emptyset \land P \in Word Vtx (G) \land \forall i \in (0 ..^\|P\| - 1) \{P (i), P (i + 1)\} \in Edg (G)) \to (G \in USHGraph \to \exists f f Walks (G) P))$
51	4 50	syl5bi	$⊢ (G \in V \land P \in Word Vtx (G)) \to (P \in WWalks (G) \to (G \in USHGraph \to \exists f f Walks (G) P))$
52	2 51	mpcom	$⊢ P \in WWalks (G) \to (G \in USHGraph \to \exists f f Walks (G) P)$
53	52	com12	$⊢ G \in USHGraph \to (P \in WWalks (G) \to \exists f f Walks (G) P)$

Metamath Proof Explorer

Theorem wlkiswwlks2

Proof