txcmp

Description: The topological product of two compact spaces is compact. (Contributed by Mario Carneiro, 14-Sep-2014) (Proof shortened 21-Mar-2015.)

		Ref	Expression
	Assertion	txcmp	$⊢ (R \in Comp \land S \in Comp) \to R \times_{t} S \in Comp$

Proof

Step	Hyp	Ref	Expression
1		cmptop	$⊢ R \in Comp \to R \in Top$
2		cmptop	$⊢ S \in Comp \to S \in Top$
3		txtop	$⊢ (R \in Top \land S \in Top) \to R \times_{t} S \in Top$
4	1 2 3	syl2an	$⊢ (R \in Comp \land S \in Comp) \to R \times_{t} S \in Top$
5		eqid	$⊢ ⋃ R = ⋃ R$
6		eqid	$⊢ ⋃ S = ⋃ S$
7		simpll	$⊢ ((R \in Comp \land S \in Comp) \land (w \in 𝒫 (R \times_{t} S) \land ⋃ (R \times_{t} S) = ⋃ w)) \to R \in Comp$
8		simplr	$⊢ ((R \in Comp \land S \in Comp) \land (w \in 𝒫 (R \times_{t} S) \land ⋃ (R \times_{t} S) = ⋃ w)) \to S \in Comp$
9		elpwi	$⊢ w \in 𝒫 (R \times_{t} S) \to w \subseteq R \times_{t} S$
10	9	ad2antrl	$⊢ ((R \in Comp \land S \in Comp) \land (w \in 𝒫 (R \times_{t} S) \land ⋃ (R \times_{t} S) = ⋃ w)) \to w \subseteq R \times_{t} S$
11	5 6	txuni	$⊢ (R \in Top \land S \in Top) \to ⋃ R \times ⋃ S = ⋃ (R \times_{t} S)$
12	1 2 11	syl2an	$⊢ (R \in Comp \land S \in Comp) \to ⋃ R \times ⋃ S = ⋃ (R \times_{t} S)$
13	12	adantr	$⊢ ((R \in Comp \land S \in Comp) \land (w \in 𝒫 (R \times_{t} S) \land ⋃ (R \times_{t} S) = ⋃ w)) \to ⋃ R \times ⋃ S = ⋃ (R \times_{t} S)$
14		simprr	$⊢ ((R \in Comp \land S \in Comp) \land (w \in 𝒫 (R \times_{t} S) \land ⋃ (R \times_{t} S) = ⋃ w)) \to ⋃ (R \times_{t} S) = ⋃ w$
15	13 14	eqtrd	$⊢ ((R \in Comp \land S \in Comp) \land (w \in 𝒫 (R \times_{t} S) \land ⋃ (R \times_{t} S) = ⋃ w)) \to ⋃ R \times ⋃ S = ⋃ w$
16	5 6 7 8 10 15	txcmplem2	$⊢ ((R \in Comp \land S \in Comp) \land (w \in 𝒫 (R \times_{t} S) \land ⋃ (R \times_{t} S) = ⋃ w)) \to \exists v \in (𝒫 w \cap Fin) ⋃ R \times ⋃ S = ⋃ v$
17	13	eqeq1d	$⊢ ((R \in Comp \land S \in Comp) \land (w \in 𝒫 (R \times_{t} S) \land ⋃ (R \times_{t} S) = ⋃ w)) \to (⋃ R \times ⋃ S = ⋃ v \leftrightarrow ⋃ (R \times_{t} S) = ⋃ v)$
18	17	rexbidv	$⊢ ((R \in Comp \land S \in Comp) \land (w \in 𝒫 (R \times_{t} S) \land ⋃ (R \times_{t} S) = ⋃ w)) \to (\exists v \in (𝒫 w \cap Fin) ⋃ R \times ⋃ S = ⋃ v \leftrightarrow \exists v \in (𝒫 w \cap Fin) ⋃ (R \times_{t} S) = ⋃ v)$
19	16 18	mpbid	$⊢ ((R \in Comp \land S \in Comp) \land (w \in 𝒫 (R \times_{t} S) \land ⋃ (R \times_{t} S) = ⋃ w)) \to \exists v \in (𝒫 w \cap Fin) ⋃ (R \times_{t} S) = ⋃ v$
20	19	expr	$⊢ ((R \in Comp \land S \in Comp) \land w \in 𝒫 (R \times_{t} S)) \to (⋃ (R \times_{t} S) = ⋃ w \to \exists v \in (𝒫 w \cap Fin) ⋃ (R \times_{t} S) = ⋃ v)$
21	20	ralrimiva	$⊢ (R \in Comp \land S \in Comp) \to \forall w \in 𝒫 (R \times_{t} S) (⋃ (R \times_{t} S) = ⋃ w \to \exists v \in (𝒫 w \cap Fin) ⋃ (R \times_{t} S) = ⋃ v)$
22		eqid	$⊢ ⋃ (R \times_{t} S) = ⋃ (R \times_{t} S)$
23	22	iscmp	$⊢ R \times_{t} S \in Comp \leftrightarrow (R \times_{t} S \in Top \land \forall w \in 𝒫 (R \times_{t} S) (⋃ (R \times_{t} S) = ⋃ w \to \exists v \in (𝒫 w \cap Fin) ⋃ (R \times_{t} S) = ⋃ v))$
24	4 21 23	sylanbrc	$⊢ (R \in Comp \land S \in Comp) \to R \times_{t} S \in Comp$

Metamath Proof Explorer

Theorem txcmp

Proof