Metamath Proof Explorer

Theorem iscnp3

Description: The predicate "the class F is a continuous function from topology J to topology K at point P ". (Contributed by NM, 15-May-2007)

		Ref	Expression
	Assertion	iscnp3	$⊢ (J \in TopOn (X) \land K \in TopOn (Y) \land P \in X) \to (F \in (J CnP K) (P) \leftrightarrow (F : X ⟶ Y \land \forall y \in K (F (P) \in y \to \exists x \in J (P \in x \land x \subseteq F^{-1} [y]))))$

Proof

Step	Hyp	Ref	Expression
1		iscnp	$⊢ (J \in TopOn (X) \land K \in TopOn (Y) \land P \in X) \to (F \in (J CnP K) (P) \leftrightarrow (F : X ⟶ Y \land \forall y \in K (F (P) \in y \to \exists x \in J (P \in x \land F [x] \subseteq y))))$
2		ffun	$⊢ F : X ⟶ Y \to Fun F$
3	2	ad2antlr	$⊢ ((J \in TopOn (X) \land F : X ⟶ Y) \land x \in J) \to Fun F$
4		toponss	$⊢ (J \in TopOn (X) \land x \in J) \to x \subseteq X$
5	4	adantlr	$⊢ ((J \in TopOn (X) \land F : X ⟶ Y) \land x \in J) \to x \subseteq X$
6		fdm	$⊢ F : X ⟶ Y \to dom F = X$
7	6	ad2antlr	$⊢ ((J \in TopOn (X) \land F : X ⟶ Y) \land x \in J) \to dom F = X$
8	5 7	sseqtrrd	$⊢ ((J \in TopOn (X) \land F : X ⟶ Y) \land x \in J) \to x \subseteq dom F$
9		funimass3	$⊢ (Fun F \land x \subseteq dom F) \to (F [x] \subseteq y \leftrightarrow x \subseteq F^{-1} [y])$
10	3 8 9	syl2anc	$⊢ ((J \in TopOn (X) \land F : X ⟶ Y) \land x \in J) \to (F [x] \subseteq y \leftrightarrow x \subseteq F^{-1} [y])$
11	10	anbi2d	$⊢ ((J \in TopOn (X) \land F : X ⟶ Y) \land x \in J) \to ((P \in x \land F [x] \subseteq y) \leftrightarrow (P \in x \land x \subseteq F^{-1} [y]))$
12	11	rexbidva	$⊢ (J \in TopOn (X) \land F : X ⟶ Y) \to (\exists x \in J (P \in x \land F [x] \subseteq y) \leftrightarrow \exists x \in J (P \in x \land x \subseteq F^{-1} [y]))$
13	12	imbi2d	$⊢ (J \in TopOn (X) \land F : X ⟶ Y) \to ((F (P) \in y \to \exists x \in J (P \in x \land F [x] \subseteq y)) \leftrightarrow (F (P) \in y \to \exists x \in J (P \in x \land x \subseteq F^{-1} [y])))$
14	13	ralbidv	$⊢ (J \in TopOn (X) \land F : X ⟶ Y) \to (\forall y \in K (F (P) \in y \to \exists x \in J (P \in x \land F [x] \subseteq y)) \leftrightarrow \forall y \in K (F (P) \in y \to \exists x \in J (P \in x \land x \subseteq F^{-1} [y])))$
15	14	pm5.32da	$⊢ J \in TopOn (X) \to ((F : X ⟶ Y \land \forall y \in K (F (P) \in y \to \exists x \in J (P \in x \land F [x] \subseteq y))) \leftrightarrow (F : X ⟶ Y \land \forall y \in K (F (P) \in y \to \exists x \in J (P \in x \land x \subseteq F^{-1} [y]))))$
16	15	3ad2ant1	$⊢ (J \in TopOn (X) \land K \in TopOn (Y) \land P \in X) \to ((F : X ⟶ Y \land \forall y \in K (F (P) \in y \to \exists x \in J (P \in x \land F [x] \subseteq y))) \leftrightarrow (F : X ⟶ Y \land \forall y \in K (F (P) \in y \to \exists x \in J (P \in x \land x \subseteq F^{-1} [y]))))$
17	1 16	bitrd	$⊢ (J \in TopOn (X) \land K \in TopOn (Y) \land P \in X) \to (F \in (J CnP K) (P) \leftrightarrow (F : X ⟶ Y \land \forall y \in K (F (P) \in y \to \exists x \in J (P \in x \land x \subseteq F^{-1} [y]))))$