fusgrhashclwwlkn

Description: The size of the set of closed walks (defined as words) with a fixed length which is a prime number is the product of the number of equivalence classes for .~ over the set of closed walks and the fixed length. (Contributed by Alexander van der Vekens, 17-Jun-2018) (Revised by AV, 1-May-2021)

	Ref	Expression
Hypotheses	erclwwlkn.w	$⊢ W = N ClWWalksN G$
	erclwwlkn.r	$⊢ \underset{˙}{\sim} = \{⟨t, u⟩ \| (t \in W \land u \in W \land \exists n \in (0 \dots N) t = u cyclShift n)\}$
Assertion	fusgrhashclwwlkn	$⊢ (G \in FinUSGraph \land N \in ℙ) \to \|W\| = \|W / \underset{˙}{\sim}\| \cdot N$

Proof

Step	Hyp	Ref	Expression
1		erclwwlkn.w	$⊢ W = N ClWWalksN G$
2		erclwwlkn.r	$⊢ \underset{˙}{\sim} = \{⟨t, u⟩ \| (t \in W \land u \in W \land \exists n \in (0 \dots N) t = u cyclShift n)\}$
3		eqid	$⊢ Vtx (G) = Vtx (G)$
4	3	fusgrvtxfi	$⊢ G \in FinUSGraph \to Vtx (G) \in Fin$
5	4	adantr	$⊢ (G \in FinUSGraph \land N \in ℙ) \to Vtx (G) \in Fin$
6	1 2	hashclwwlkn0	$⊢ Vtx (G) \in Fin \to \|W\| = \sum_{x \in W / \underset{˙}{\sim}} \|x\|$
7	5 6	syl	$⊢ (G \in FinUSGraph \land N \in ℙ) \to \|W\| = \sum_{x \in W / \underset{˙}{\sim}} \|x\|$
8		fusgrusgr	$⊢ G \in FinUSGraph \to G \in USGraph$
9		usgrumgr	$⊢ G \in USGraph \to G \in UMGraph$
10	8 9	syl	$⊢ G \in FinUSGraph \to G \in UMGraph$
11	1 2	umgrhashecclwwlk	$⊢ (G \in UMGraph \land N \in ℙ) \to (x \in (W / \underset{˙}{\sim}) \to \|x\| = N)$
12	10 11	sylan	$⊢ (G \in FinUSGraph \land N \in ℙ) \to (x \in (W / \underset{˙}{\sim}) \to \|x\| = N)$
13	12	imp	$⊢ ((G \in FinUSGraph \land N \in ℙ) \land x \in (W / \underset{˙}{\sim})) \to \|x\| = N$
14	13	sumeq2dv	$⊢ (G \in FinUSGraph \land N \in ℙ) \to \sum_{x \in W / \underset{˙}{\sim}} \|x\| = \sum_{x \in W / \underset{˙}{\sim}} N$
15	1 2	qerclwwlknfi	$⊢ Vtx (G) \in Fin \to W / \underset{˙}{\sim} \in Fin$
16	5 15	syl	$⊢ (G \in FinUSGraph \land N \in ℙ) \to W / \underset{˙}{\sim} \in Fin$
17		prmnn	$⊢ N \in ℙ \to N \in ℕ$
18	17	nncnd	$⊢ N \in ℙ \to N \in ℂ$
19	18	adantl	$⊢ (G \in FinUSGraph \land N \in ℙ) \to N \in ℂ$
20		fsumconst	$⊢ (W / \underset{˙}{\sim} \in Fin \land N \in ℂ) \to \sum_{x \in W / \underset{˙}{\sim}} N = \|W / \underset{˙}{\sim}\| \cdot N$
21	16 19 20	syl2anc	$⊢ (G \in FinUSGraph \land N \in ℙ) \to \sum_{x \in W / \underset{˙}{\sim}} N = \|W / \underset{˙}{\sim}\| \cdot N$
22	7 14 21	3eqtrd	$⊢ (G \in FinUSGraph \land N \in ℙ) \to \|W\| = \|W / \underset{˙}{\sim}\| \cdot N$

Metamath Proof Explorer

Theorem fusgrhashclwwlkn

Proof