cldregopn

Description: A set if regularly open iff it is the interior of some closed set. (Contributed by Jeff Hankins, 27-Sep-2009)

		Ref	Expression
	Hypothesis	opnregcld.1	$⊢ X = ⋃ J$
	Assertion	cldregopn	$⊢ (J \in Top \land A \subseteq X) \to (int (J) (cls (J) (A)) = A \leftrightarrow \exists c \in Clsd (J) A = int (J) (c))$

Proof

Step	Hyp	Ref	Expression
1		opnregcld.1	$⊢ X = ⋃ J$
2	1	clscld	$⊢ (J \in Top \land A \subseteq X) \to cls (J) (A) \in Clsd (J)$
3		eqcom	$⊢ int (J) (cls (J) (A)) = A \leftrightarrow A = int (J) (cls (J) (A))$
4	3	biimpi	$⊢ int (J) (cls (J) (A)) = A \to A = int (J) (cls (J) (A))$
5		fveq2	$⊢ c = cls (J) (A) \to int (J) (c) = int (J) (cls (J) (A))$
6	5	rspceeqv	$⊢ (cls (J) (A) \in Clsd (J) \land A = int (J) (cls (J) (A))) \to \exists c \in Clsd (J) A = int (J) (c)$
7	2 4 6	syl2an	$⊢ ((J \in Top \land A \subseteq X) \land int (J) (cls (J) (A)) = A) \to \exists c \in Clsd (J) A = int (J) (c)$
8	7	ex	$⊢ (J \in Top \land A \subseteq X) \to (int (J) (cls (J) (A)) = A \to \exists c \in Clsd (J) A = int (J) (c))$
9		cldrcl	$⊢ c \in Clsd (J) \to J \in Top$
10	1	cldss	$⊢ c \in Clsd (J) \to c \subseteq X$
11	1	ntrss2	$⊢ (J \in Top \land c \subseteq X) \to int (J) (c) \subseteq c$
12	9 10 11	syl2anc	$⊢ c \in Clsd (J) \to int (J) (c) \subseteq c$
13	1	clsss2	$⊢ (c \in Clsd (J) \land int (J) (c) \subseteq c) \to cls (J) (int (J) (c)) \subseteq c$
14	12 13	mpdan	$⊢ c \in Clsd (J) \to cls (J) (int (J) (c)) \subseteq c$
15	1	ntrss	$⊢ (J \in Top \land c \subseteq X \land cls (J) (int (J) (c)) \subseteq c) \to int (J) (cls (J) (int (J) (c))) \subseteq int (J) (c)$
16	9 10 14 15	syl3anc	$⊢ c \in Clsd (J) \to int (J) (cls (J) (int (J) (c))) \subseteq int (J) (c)$
17	1	ntridm	$⊢ (J \in Top \land c \subseteq X) \to int (J) (int (J) (c)) = int (J) (c)$
18	9 10 17	syl2anc	$⊢ c \in Clsd (J) \to int (J) (int (J) (c)) = int (J) (c)$
19	1	ntrss3	$⊢ (J \in Top \land c \subseteq X) \to int (J) (c) \subseteq X$
20	9 10 19	syl2anc	$⊢ c \in Clsd (J) \to int (J) (c) \subseteq X$
21	1	clsss3	$⊢ (J \in Top \land int (J) (c) \subseteq X) \to cls (J) (int (J) (c)) \subseteq X$
22	9 20 21	syl2anc	$⊢ c \in Clsd (J) \to cls (J) (int (J) (c)) \subseteq X$
23	1	sscls	$⊢ (J \in Top \land int (J) (c) \subseteq X) \to int (J) (c) \subseteq cls (J) (int (J) (c))$
24	9 20 23	syl2anc	$⊢ c \in Clsd (J) \to int (J) (c) \subseteq cls (J) (int (J) (c))$
25	1	ntrss	$⊢ (J \in Top \land cls (J) (int (J) (c)) \subseteq X \land int (J) (c) \subseteq cls (J) (int (J) (c))) \to int (J) (int (J) (c)) \subseteq int (J) (cls (J) (int (J) (c)))$
26	9 22 24 25	syl3anc	$⊢ c \in Clsd (J) \to int (J) (int (J) (c)) \subseteq int (J) (cls (J) (int (J) (c)))$
27	18 26	eqsstrrd	$⊢ c \in Clsd (J) \to int (J) (c) \subseteq int (J) (cls (J) (int (J) (c)))$
28	16 27	eqssd	$⊢ c \in Clsd (J) \to int (J) (cls (J) (int (J) (c))) = int (J) (c)$
29	28	adantl	$⊢ ((J \in Top \land A \subseteq X) \land c \in Clsd (J)) \to int (J) (cls (J) (int (J) (c))) = int (J) (c)$
30		2fveq3	$⊢ A = int (J) (c) \to int (J) (cls (J) (A)) = int (J) (cls (J) (int (J) (c)))$
31		id	$⊢ A = int (J) (c) \to A = int (J) (c)$
32	30 31	eqeq12d	$⊢ A = int (J) (c) \to (int (J) (cls (J) (A)) = A \leftrightarrow int (J) (cls (J) (int (J) (c))) = int (J) (c))$
33	29 32	syl5ibrcom	$⊢ ((J \in Top \land A \subseteq X) \land c \in Clsd (J)) \to (A = int (J) (c) \to int (J) (cls (J) (A)) = A)$
34	33	rexlimdva	$⊢ (J \in Top \land A \subseteq X) \to (\exists c \in Clsd (J) A = int (J) (c) \to int (J) (cls (J) (A)) = A)$
35	8 34	impbid	$⊢ (J \in Top \land A \subseteq X) \to (int (J) (cls (J) (A)) = A \leftrightarrow \exists c \in Clsd (J) A = int (J) (c))$

Metamath Proof Explorer

Theorem cldregopn

Proof