distgp

Description: Any group equipped with the discrete topology is a topological group. (Contributed by Mario Carneiro, 14-Aug-2015)

	Ref	Expression
Hypotheses	distgp.1	$⊢ B = {Base}_{G}$
	distgp.2	$⊢ J = TopOpen (G)$
Assertion	distgp	$⊢ (G \in Grp \land J = 𝒫 B) \to G \in TopGrp$

Proof

Step	Hyp	Ref	Expression
1		distgp.1	$⊢ B = {Base}_{G}$
2		distgp.2	$⊢ J = TopOpen (G)$
3		simpl	$⊢ (G \in Grp \land J = 𝒫 B) \to G \in Grp$
4		simpr	$⊢ (G \in Grp \land J = 𝒫 B) \to J = 𝒫 B$
5	1	fvexi	$⊢ B \in V$
6		distopon	$⊢ B \in V \to 𝒫 B \in TopOn (B)$
7	5 6	ax-mp	$⊢ 𝒫 B \in TopOn (B)$
8	4 7	eqeltrdi	$⊢ (G \in Grp \land J = 𝒫 B) \to J \in TopOn (B)$
9	1 2	istps	$⊢ G \in TopSp \leftrightarrow J \in TopOn (B)$
10	8 9	sylibr	$⊢ (G \in Grp \land J = 𝒫 B) \to G \in TopSp$
11		eqid	$⊢ -_{G} = -_{G}$
12	1 11	grpsubf	$⊢ G \in Grp \to -_{G} : B \times B ⟶ B$
13	12	adantr	$⊢ (G \in Grp \land J = 𝒫 B) \to -_{G} : B \times B ⟶ B$
14	5 5	xpex	$⊢ B \times B \in V$
15	5 14	elmap	$⊢ -_{G} \in (B^{(B \times B)}) \leftrightarrow -_{G} : B \times B ⟶ B$
16	13 15	sylibr	$⊢ (G \in Grp \land J = 𝒫 B) \to -_{G} \in (B^{(B \times B)})$
17	4 4	oveq12d	$⊢ (G \in Grp \land J = 𝒫 B) \to J \times_{t} J = 𝒫 B \times_{t} 𝒫 B$
18		txdis	$⊢ (B \in V \land B \in V) \to 𝒫 B \times_{t} 𝒫 B = 𝒫 (B \times B)$
19	5 5 18	mp2an	$⊢ 𝒫 B \times_{t} 𝒫 B = 𝒫 (B \times B)$
20	17 19	eqtrdi	$⊢ (G \in Grp \land J = 𝒫 B) \to J \times_{t} J = 𝒫 (B \times B)$
21	20	oveq1d	$⊢ (G \in Grp \land J = 𝒫 B) \to (J \times_{t} J) Cn J = 𝒫 (B \times B) Cn J$
22		cndis	$⊢ (B \times B \in V \land J \in TopOn (B)) \to 𝒫 (B \times B) Cn J = B^{(B \times B)}$
23	14 8 22	sylancr	$⊢ (G \in Grp \land J = 𝒫 B) \to 𝒫 (B \times B) Cn J = B^{(B \times B)}$
24	21 23	eqtrd	$⊢ (G \in Grp \land J = 𝒫 B) \to (J \times_{t} J) Cn J = B^{(B \times B)}$
25	16 24	eleqtrrd	$⊢ (G \in Grp \land J = 𝒫 B) \to -_{G} \in ((J \times_{t} J) Cn J)$
26	2 11	istgp2	$⊢ G \in TopGrp \leftrightarrow (G \in Grp \land G \in TopSp \land -_{G} \in ((J \times_{t} J) Cn J))$
27	3 10 25 26	syl3anbrc	$⊢ (G \in Grp \land J = 𝒫 B) \to G \in TopGrp$

Metamath Proof Explorer

Theorem distgp

Proof