isnrm2

Description: An alternate characterization of normality. This is the important property in the proof of Urysohn's lemma. (Contributed by Jeff Hankins, 1-Feb-2010) (Proof shortened by Mario Carneiro, 24-Aug-2015)

		Ref	Expression
	Assertion	isnrm2	$⊢ J \in Nrm \leftrightarrow (J \in Top \land \forall c \in Clsd (J) \forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)))$

Proof

Step	Hyp	Ref	Expression
1		nrmtop	$⊢ J \in Nrm \to J \in Top$
2		nrmsep2	$⊢ (J \in Nrm \land (c \in Clsd (J) \land d \in Clsd (J) \land c \cap d = \emptyset)) \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)$
3	2	3exp2	$⊢ J \in Nrm \to (c \in Clsd (J) \to (d \in Clsd (J) \to (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset))))$
4	3	impd	$⊢ J \in Nrm \to ((c \in Clsd (J) \land d \in Clsd (J)) \to (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)))$
5	4	ralrimivv	$⊢ J \in Nrm \to \forall c \in Clsd (J) \forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset))$
6	1 5	jca	$⊢ J \in Nrm \to (J \in Top \land \forall c \in Clsd (J) \forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)))$
7		simpl	$⊢ (J \in Top \land \forall c \in Clsd (J) \forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset))) \to J \in Top$
8		eqid	$⊢ ⋃ J = ⋃ J$
9	8	opncld	$⊢ (J \in Top \land x \in J) \to ⋃ J ∖ x \in Clsd (J)$
10	9	adantr	$⊢ ((J \in Top \land x \in J) \land c \in Clsd (J)) \to ⋃ J ∖ x \in Clsd (J)$
11		ineq2	$⊢ d = ⋃ J ∖ x \to c \cap d = c \cap (⋃ J ∖ x)$
12	11	eqeq1d	$⊢ d = ⋃ J ∖ x \to (c \cap d = \emptyset \leftrightarrow c \cap (⋃ J ∖ x) = \emptyset)$
13		ineq2	$⊢ d = ⋃ J ∖ x \to cls (J) (o) \cap d = cls (J) (o) \cap (⋃ J ∖ x)$
14	13	eqeq1d	$⊢ d = ⋃ J ∖ x \to (cls (J) (o) \cap d = \emptyset \leftrightarrow cls (J) (o) \cap (⋃ J ∖ x) = \emptyset)$
15	14	anbi2d	$⊢ d = ⋃ J ∖ x \to ((c \subseteq o \land cls (J) (o) \cap d = \emptyset) \leftrightarrow (c \subseteq o \land cls (J) (o) \cap (⋃ J ∖ x) = \emptyset))$
16	15	rexbidv	$⊢ d = ⋃ J ∖ x \to (\exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset) \leftrightarrow \exists o \in J (c \subseteq o \land cls (J) (o) \cap (⋃ J ∖ x) = \emptyset))$
17	12 16	imbi12d	$⊢ d = ⋃ J ∖ x \to ((c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)) \leftrightarrow (c \cap (⋃ J ∖ x) = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap (⋃ J ∖ x) = \emptyset)))$
18	17	rspcv	$⊢ ⋃ J ∖ x \in Clsd (J) \to (\forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)) \to (c \cap (⋃ J ∖ x) = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap (⋃ J ∖ x) = \emptyset)))$
19	10 18	syl	$⊢ ((J \in Top \land x \in J) \land c \in Clsd (J)) \to (\forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)) \to (c \cap (⋃ J ∖ x) = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap (⋃ J ∖ x) = \emptyset)))$
20		inssdif0	$⊢ c \cap ⋃ J \subseteq x \leftrightarrow c \cap (⋃ J ∖ x) = \emptyset$
21	8	cldss	$⊢ c \in Clsd (J) \to c \subseteq ⋃ J$
22	21	adantl	$⊢ ((J \in Top \land x \in J) \land c \in Clsd (J)) \to c \subseteq ⋃ J$
23		dfss2	$⊢ c \subseteq ⋃ J \leftrightarrow c \cap ⋃ J = c$
24	22 23	sylib	$⊢ ((J \in Top \land x \in J) \land c \in Clsd (J)) \to c \cap ⋃ J = c$
25	24	sseq1d	$⊢ ((J \in Top \land x \in J) \land c \in Clsd (J)) \to (c \cap ⋃ J \subseteq x \leftrightarrow c \subseteq x)$
26	20 25	bitr3id	$⊢ ((J \in Top \land x \in J) \land c \in Clsd (J)) \to (c \cap (⋃ J ∖ x) = \emptyset \leftrightarrow c \subseteq x)$
27		inssdif0	$⊢ cls (J) (o) \cap ⋃ J \subseteq x \leftrightarrow cls (J) (o) \cap (⋃ J ∖ x) = \emptyset$
28		simpll	$⊢ ((J \in Top \land x \in J) \land c \in Clsd (J)) \to J \in Top$
29		elssuni	$⊢ o \in J \to o \subseteq ⋃ J$
30	8	clsss3	$⊢ (J \in Top \land o \subseteq ⋃ J) \to cls (J) (o) \subseteq ⋃ J$
31	28 29 30	syl2an	$⊢ (((J \in Top \land x \in J) \land c \in Clsd (J)) \land o \in J) \to cls (J) (o) \subseteq ⋃ J$
32		dfss2	$⊢ cls (J) (o) \subseteq ⋃ J \leftrightarrow cls (J) (o) \cap ⋃ J = cls (J) (o)$
33	31 32	sylib	$⊢ (((J \in Top \land x \in J) \land c \in Clsd (J)) \land o \in J) \to cls (J) (o) \cap ⋃ J = cls (J) (o)$
34	33	sseq1d	$⊢ (((J \in Top \land x \in J) \land c \in Clsd (J)) \land o \in J) \to (cls (J) (o) \cap ⋃ J \subseteq x \leftrightarrow cls (J) (o) \subseteq x)$
35	27 34	bitr3id	$⊢ (((J \in Top \land x \in J) \land c \in Clsd (J)) \land o \in J) \to (cls (J) (o) \cap (⋃ J ∖ x) = \emptyset \leftrightarrow cls (J) (o) \subseteq x)$
36	35	anbi2d	$⊢ (((J \in Top \land x \in J) \land c \in Clsd (J)) \land o \in J) \to ((c \subseteq o \land cls (J) (o) \cap (⋃ J ∖ x) = \emptyset) \leftrightarrow (c \subseteq o \land cls (J) (o) \subseteq x))$
37	36	rexbidva	$⊢ ((J \in Top \land x \in J) \land c \in Clsd (J)) \to (\exists o \in J (c \subseteq o \land cls (J) (o) \cap (⋃ J ∖ x) = \emptyset) \leftrightarrow \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x))$
38	26 37	imbi12d	$⊢ ((J \in Top \land x \in J) \land c \in Clsd (J)) \to ((c \cap (⋃ J ∖ x) = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap (⋃ J ∖ x) = \emptyset)) \leftrightarrow (c \subseteq x \to \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x)))$
39	19 38	sylibd	$⊢ ((J \in Top \land x \in J) \land c \in Clsd (J)) \to (\forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)) \to (c \subseteq x \to \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x)))$
40	39	ralimdva	$⊢ (J \in Top \land x \in J) \to (\forall c \in Clsd (J) \forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)) \to \forall c \in Clsd (J) (c \subseteq x \to \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x)))$
41		elin	$⊢ c \in (Clsd (J) \cap 𝒫 x) \leftrightarrow (c \in Clsd (J) \land c \in 𝒫 x)$
42		velpw	$⊢ c \in 𝒫 x \leftrightarrow c \subseteq x$
43	42	anbi2i	$⊢ (c \in Clsd (J) \land c \in 𝒫 x) \leftrightarrow (c \in Clsd (J) \land c \subseteq x)$
44	41 43	bitri	$⊢ c \in (Clsd (J) \cap 𝒫 x) \leftrightarrow (c \in Clsd (J) \land c \subseteq x)$
45	44	imbi1i	$⊢ (c \in (Clsd (J) \cap 𝒫 x) \to \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x)) \leftrightarrow ((c \in Clsd (J) \land c \subseteq x) \to \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x))$
46		impexp	$⊢ ((c \in Clsd (J) \land c \subseteq x) \to \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x)) \leftrightarrow (c \in Clsd (J) \to (c \subseteq x \to \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x)))$
47	45 46	bitri	$⊢ (c \in (Clsd (J) \cap 𝒫 x) \to \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x)) \leftrightarrow (c \in Clsd (J) \to (c \subseteq x \to \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x)))$
48	47	ralbii2	$⊢ \forall c \in (Clsd (J) \cap 𝒫 x) \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x) \leftrightarrow \forall c \in Clsd (J) (c \subseteq x \to \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x))$
49	40 48	imbitrrdi	$⊢ (J \in Top \land x \in J) \to (\forall c \in Clsd (J) \forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)) \to \forall c \in (Clsd (J) \cap 𝒫 x) \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x))$
50	49	ralrimdva	$⊢ J \in Top \to (\forall c \in Clsd (J) \forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)) \to \forall x \in J \forall c \in (Clsd (J) \cap 𝒫 x) \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x))$
51	50	imp	$⊢ (J \in Top \land \forall c \in Clsd (J) \forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset))) \to \forall x \in J \forall c \in (Clsd (J) \cap 𝒫 x) \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x)$
52		isnrm	$⊢ J \in Nrm \leftrightarrow (J \in Top \land \forall x \in J \forall c \in (Clsd (J) \cap 𝒫 x) \exists o \in J (c \subseteq o \land cls (J) (o) \subseteq x))$
53	7 51 52	sylanbrc	$⊢ (J \in Top \land \forall c \in Clsd (J) \forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset))) \to J \in Nrm$
54	6 53	impbii	$⊢ J \in Nrm \leftrightarrow (J \in Top \land \forall c \in Clsd (J) \forall d \in Clsd (J) (c \cap d = \emptyset \to \exists o \in J (c \subseteq o \land cls (J) (o) \cap d = \emptyset)))$

Metamath Proof Explorer

Theorem isnrm2

Proof