ressusp

Description: The restriction of a uniform topological space to an open set is a uniform space. (Contributed by Thierry Arnoux, 16-Dec-2017)

	Ref	Expression
Hypotheses	ressusp.1	$⊢ B = {Base}_{W}$
	ressusp.2	$⊢ J = TopOpen (W)$
Assertion	ressusp	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to W ↾_{𝑠} A \in UnifSp$

Proof

Step	Hyp	Ref	Expression
1		ressusp.1	$⊢ B = {Base}_{W}$
2		ressusp.2	$⊢ J = TopOpen (W)$
3		ressuss	$⊢ A \in J \to UnifSt (W ↾_{𝑠} A) = UnifSt (W) ↾_{𝑡} (A \times A)$
4	3	3ad2ant3	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to UnifSt (W ↾_{𝑠} A) = UnifSt (W) ↾_{𝑡} (A \times A)$
5		simp1	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to W \in UnifSp$
6		eqid	$⊢ UnifSt (W) = UnifSt (W)$
7	1 6 2	isusp	$⊢ W \in UnifSp \leftrightarrow (UnifSt (W) \in UnifOn (B) \land J = unifTop (UnifSt (W)))$
8	5 7	sylib	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to (UnifSt (W) \in UnifOn (B) \land J = unifTop (UnifSt (W)))$
9	8	simpld	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to UnifSt (W) \in UnifOn (B)$
10		simp2	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to W \in TopSp$
11	1 2	istps	$⊢ W \in TopSp \leftrightarrow J \in TopOn (B)$
12	10 11	sylib	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to J \in TopOn (B)$
13		simp3	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to A \in J$
14		toponss	$⊢ (J \in TopOn (B) \land A \in J) \to A \subseteq B$
15	12 13 14	syl2anc	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to A \subseteq B$
16		trust	$⊢ (UnifSt (W) \in UnifOn (B) \land A \subseteq B) \to UnifSt (W) ↾_{𝑡} (A \times A) \in UnifOn (A)$
17	9 15 16	syl2anc	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to UnifSt (W) ↾_{𝑡} (A \times A) \in UnifOn (A)$
18	4 17	eqeltrd	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to UnifSt (W ↾_{𝑠} A) \in UnifOn (A)$
19		eqid	$⊢ W ↾_{𝑠} A = W ↾_{𝑠} A$
20	19 1	ressbas2	$⊢ A \subseteq B \to A = {Base}_{(W ↾_{𝑠} A)}$
21	15 20	syl	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to A = {Base}_{(W ↾_{𝑠} A)}$
22	21	fveq2d	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to UnifOn (A) = UnifOn ({Base}_{(W ↾_{𝑠} A)})$
23	18 22	eleqtrd	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to UnifSt (W ↾_{𝑠} A) \in UnifOn ({Base}_{(W ↾_{𝑠} A)})$
24	8	simprd	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to J = unifTop (UnifSt (W))$
25	13 24	eleqtrd	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to A \in unifTop (UnifSt (W))$
26		restutopopn	$⊢ (UnifSt (W) \in UnifOn (B) \land A \in unifTop (UnifSt (W))) \to unifTop (UnifSt (W)) ↾_{𝑡} A = unifTop (UnifSt (W) ↾_{𝑡} (A \times A))$
27	9 25 26	syl2anc	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to unifTop (UnifSt (W)) ↾_{𝑡} A = unifTop (UnifSt (W) ↾_{𝑡} (A \times A))$
28	24	oveq1d	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to J ↾_{𝑡} A = unifTop (UnifSt (W)) ↾_{𝑡} A$
29	4	fveq2d	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to unifTop (UnifSt (W ↾_{𝑠} A)) = unifTop (UnifSt (W) ↾_{𝑡} (A \times A))$
30	27 28 29	3eqtr4d	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to J ↾_{𝑡} A = unifTop (UnifSt (W ↾_{𝑠} A))$
31		eqid	$⊢ {Base}_{(W ↾_{𝑠} A)} = {Base}_{(W ↾_{𝑠} A)}$
32		eqid	$⊢ UnifSt (W ↾_{𝑠} A) = UnifSt (W ↾_{𝑠} A)$
33	19 2	resstopn	$⊢ J ↾_{𝑡} A = TopOpen (W ↾_{𝑠} A)$
34	31 32 33	isusp	$⊢ W ↾_{𝑠} A \in UnifSp \leftrightarrow (UnifSt (W ↾_{𝑠} A) \in UnifOn ({Base}_{(W ↾_{𝑠} A)}) \land J ↾_{𝑡} A = unifTop (UnifSt (W ↾_{𝑠} A)))$
35	23 30 34	sylanbrc	$⊢ (W \in UnifSp \land W \in TopSp \land A \in J) \to W ↾_{𝑠} A \in UnifSp$

Metamath Proof Explorer

Theorem ressusp

Proof