isflf

Description: The property of being a limit point of a function. (Contributed by Jeff Hankins, 8-Nov-2009) (Revised by Stefan O'Rear, 7-Aug-2015)

		Ref	Expression
	Assertion	isflf	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to (A \in (J fLimf L) (F) \leftrightarrow (A \in X \land \forall o \in J (A \in o \to \exists s \in L F [s] \subseteq o)))$

Proof

Step	Hyp	Ref	Expression
1		flfval	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to (J fLimf L) (F) = J fLim (X FilMap F) (L)$
2	1	eleq2d	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to (A \in (J fLimf L) (F) \leftrightarrow A \in (J fLim (X FilMap F) (L)))$
3		simp1	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to J \in TopOn (X)$
4		toponmax	$⊢ J \in TopOn (X) \to X \in J$
5	4	3ad2ant1	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to X \in J$
6		filfbas	$⊢ L \in Fil (Y) \to L \in fBas (Y)$
7	6	3ad2ant2	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to L \in fBas (Y)$
8		simp3	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to F : Y ⟶ X$
9		fmfil	$⊢ (X \in J \land L \in fBas (Y) \land F : Y ⟶ X) \to (X FilMap F) (L) \in Fil (X)$
10	5 7 8 9	syl3anc	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to (X FilMap F) (L) \in Fil (X)$
11		flimopn	$⊢ (J \in TopOn (X) \land (X FilMap F) (L) \in Fil (X)) \to (A \in (J fLim (X FilMap F) (L)) \leftrightarrow (A \in X \land \forall o \in J (A \in o \to o \in (X FilMap F) (L))))$
12	3 10 11	syl2anc	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to (A \in (J fLim (X FilMap F) (L)) \leftrightarrow (A \in X \land \forall o \in J (A \in o \to o \in (X FilMap F) (L))))$
13		toponss	$⊢ (J \in TopOn (X) \land o \in J) \to o \subseteq X$
14	3 13	sylan	$⊢ ((J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \land o \in J) \to o \subseteq X$
15		elfm	$⊢ (X \in J \land L \in fBas (Y) \land F : Y ⟶ X) \to (o \in (X FilMap F) (L) \leftrightarrow (o \subseteq X \land \exists s \in L F [s] \subseteq o))$
16	5 7 8 15	syl3anc	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to (o \in (X FilMap F) (L) \leftrightarrow (o \subseteq X \land \exists s \in L F [s] \subseteq o))$
17	16	adantr	$⊢ ((J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \land o \in J) \to (o \in (X FilMap F) (L) \leftrightarrow (o \subseteq X \land \exists s \in L F [s] \subseteq o))$
18	14 17	mpbirand	$⊢ ((J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \land o \in J) \to (o \in (X FilMap F) (L) \leftrightarrow \exists s \in L F [s] \subseteq o)$
19	18	imbi2d	$⊢ ((J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \land o \in J) \to ((A \in o \to o \in (X FilMap F) (L)) \leftrightarrow (A \in o \to \exists s \in L F [s] \subseteq o))$
20	19	ralbidva	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to (\forall o \in J (A \in o \to o \in (X FilMap F) (L)) \leftrightarrow \forall o \in J (A \in o \to \exists s \in L F [s] \subseteq o))$
21	20	anbi2d	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to ((A \in X \land \forall o \in J (A \in o \to o \in (X FilMap F) (L))) \leftrightarrow (A \in X \land \forall o \in J (A \in o \to \exists s \in L F [s] \subseteq o)))$
22	2 12 21	3bitrd	$⊢ (J \in TopOn (X) \land L \in Fil (Y) \land F : Y ⟶ X) \to (A \in (J fLimf L) (F) \leftrightarrow (A \in X \land \forall o \in J (A \in o \to \exists s \in L F [s] \subseteq o)))$

Metamath Proof Explorer

Theorem isflf

Proof