Metamath Proof Explorer

Theorem metnrm

Description: A metric space is normal. (Contributed by Jeff Hankins, 31-Aug-2013) (Revised by Mario Carneiro, 5-Sep-2015) (Proof shortened by AV, 30-Sep-2020)

		Ref	Expression
	Hypothesis	metnrm.j	$⊢ J = MetOpen (D)$
	Assertion	metnrm	$⊢ D \in ∞Met (X) \to J \in Nrm$

Proof

Step	Hyp	Ref	Expression
1		metnrm.j	$⊢ J = MetOpen (D)$
2	1	mopntop	$⊢ D \in ∞Met (X) \to J \in Top$
3		eqid	$⊢ (u \in X ⟼ sup (ran (v \in x ⟼ u D v) ℝ^{} <)) = (u \in X ⟼ sup (ran (v \in x ⟼ u D v) ℝ^{} <))$
4		simp1	$⊢ (D \in ∞Met (X) \land (x \in Clsd (J) \land y \in Clsd (J)) \land x \cap y = \emptyset) \to D \in ∞Met (X)$
5		simp2l	$⊢ (D \in ∞Met (X) \land (x \in Clsd (J) \land y \in Clsd (J)) \land x \cap y = \emptyset) \to x \in Clsd (J)$
6		simp2r	$⊢ (D \in ∞Met (X) \land (x \in Clsd (J) \land y \in Clsd (J)) \land x \cap y = \emptyset) \to y \in Clsd (J)$
7		simp3	$⊢ (D \in ∞Met (X) \land (x \in Clsd (J) \land y \in Clsd (J)) \land x \cap y = \emptyset) \to x \cap y = \emptyset$
8		eqid	$⊢ ⋃_{s \in y} (s ball (D) (\frac{if (1 \leq (u \in X ⟼ sup (ran (v \in x ⟼ u D v) ℝ^{} <)) (s), 1, (u \in X ⟼ sup (ran (v \in x ⟼ u D v) ℝ^{} <)) (s))}{2})) = ⋃_{s \in y} (s ball (D) (\frac{if (1 \leq (u \in X ⟼ sup (ran (v \in x ⟼ u D v) ℝ^{} <)) (s), 1, (u \in X ⟼ sup (ran (v \in x ⟼ u D v) ℝ^{} <)) (s))}{2}))$
9		eqid	$⊢ (u \in X ⟼ sup (ran (v \in y ⟼ u D v) ℝ^{} <)) = (u \in X ⟼ sup (ran (v \in y ⟼ u D v) ℝ^{} <))$
10		eqid	$⊢ ⋃_{t \in x} (t ball (D) (\frac{if (1 \leq (u \in X ⟼ sup (ran (v \in y ⟼ u D v) ℝ^{} <)) (t), 1, (u \in X ⟼ sup (ran (v \in y ⟼ u D v) ℝ^{} <)) (t))}{2})) = ⋃_{t \in x} (t ball (D) (\frac{if (1 \leq (u \in X ⟼ sup (ran (v \in y ⟼ u D v) ℝ^{} <)) (t), 1, (u \in X ⟼ sup (ran (v \in y ⟼ u D v) ℝ^{} <)) (t))}{2}))$
11	3 1 4 5 6 7 8 9 10	metnrmlem3	$⊢ (D \in ∞Met (X) \land (x \in Clsd (J) \land y \in Clsd (J)) \land x \cap y = \emptyset) \to \exists z \in J \exists w \in J (x \subseteq z \land y \subseteq w \land z \cap w = \emptyset)$
12	11	3expia	$⊢ (D \in ∞Met (X) \land (x \in Clsd (J) \land y \in Clsd (J))) \to (x \cap y = \emptyset \to \exists z \in J \exists w \in J (x \subseteq z \land y \subseteq w \land z \cap w = \emptyset))$
13	12	ralrimivva	$⊢ D \in ∞Met (X) \to \forall x \in Clsd (J) \forall y \in Clsd (J) (x \cap y = \emptyset \to \exists z \in J \exists w \in J (x \subseteq z \land y \subseteq w \land z \cap w = \emptyset))$
14		isnrm3	$⊢ J \in Nrm \leftrightarrow (J \in Top \land \forall x \in Clsd (J) \forall y \in Clsd (J) (x \cap y = \emptyset \to \exists z \in J \exists w \in J (x \subseteq z \land y \subseteq w \land z \cap w = \emptyset)))$
15	2 13 14	sylanbrc	$⊢ D \in ∞Met (X) \to J \in Nrm$