Metamath Proof Explorer

Theorem cnlimc

Description: F is a continuous function iff the limit of the function at each point equals the value of the function. (Contributed by Mario Carneiro, 28-Dec-2016)

		Ref	Expression
	Assertion	cnlimc	$⊢ A \subseteq ℂ \to (F : A \underset{cn}{⟶} ℂ \leftrightarrow (F : A ⟶ ℂ \land \forall x \in A F (x) \in (F {lim}_{ℂ} x)))$

Proof

Step	Hyp	Ref	Expression
1		ssid	$⊢ ℂ \subseteq ℂ$
2		eqid	$⊢ TopOpen (ℂ_{fld}) = TopOpen (ℂ_{fld})$
3		eqid	$⊢ TopOpen (ℂ_{fld}) ↾_{𝑡} A = TopOpen (ℂ_{fld}) ↾_{𝑡} A$
4	2	cnfldtopon	$⊢ TopOpen (ℂ_{fld}) \in TopOn (ℂ)$
5	4	toponrestid	$⊢ TopOpen (ℂ_{fld}) = TopOpen (ℂ_{fld}) ↾_{𝑡} ℂ$
6	2 3 5	cncfcn	$⊢ (A \subseteq ℂ \land ℂ \subseteq ℂ) \to A \underset{cn}{⟶} ℂ = (TopOpen (ℂ_{fld}) ↾_{𝑡} A) Cn TopOpen (ℂ_{fld})$
7	1 6	mpan2	$⊢ A \subseteq ℂ \to A \underset{cn}{⟶} ℂ = (TopOpen (ℂ_{fld}) ↾_{𝑡} A) Cn TopOpen (ℂ_{fld})$
8	7	eleq2d	$⊢ A \subseteq ℂ \to (F : A \underset{cn}{⟶} ℂ \leftrightarrow F \in ((TopOpen (ℂ_{fld}) ↾_{𝑡} A) Cn TopOpen (ℂ_{fld})))$
9		resttopon	$⊢ (TopOpen (ℂ_{fld}) \in TopOn (ℂ) \land A \subseteq ℂ) \to TopOpen (ℂ_{fld}) ↾_{𝑡} A \in TopOn (A)$
10	4 9	mpan	$⊢ A \subseteq ℂ \to TopOpen (ℂ_{fld}) ↾_{𝑡} A \in TopOn (A)$
11		cncnp	$⊢ (TopOpen (ℂ_{fld}) ↾_{𝑡} A \in TopOn (A) \land TopOpen (ℂ_{fld}) \in TopOn (ℂ)) \to (F \in ((TopOpen (ℂ_{fld}) ↾_{𝑡} A) Cn TopOpen (ℂ_{fld})) \leftrightarrow (F : A ⟶ ℂ \land \forall x \in A F \in ((TopOpen (ℂ_{fld}) ↾_{𝑡} A) CnP TopOpen (ℂ_{fld})) (x)))$
12	10 4 11	sylancl	$⊢ A \subseteq ℂ \to (F \in ((TopOpen (ℂ_{fld}) ↾_{𝑡} A) Cn TopOpen (ℂ_{fld})) \leftrightarrow (F : A ⟶ ℂ \land \forall x \in A F \in ((TopOpen (ℂ_{fld}) ↾_{𝑡} A) CnP TopOpen (ℂ_{fld})) (x)))$
13	2 3	cnplimc	$⊢ (A \subseteq ℂ \land x \in A) \to (F \in ((TopOpen (ℂ_{fld}) ↾_{𝑡} A) CnP TopOpen (ℂ_{fld})) (x) \leftrightarrow (F : A ⟶ ℂ \land F (x) \in (F {lim}_{ℂ} x)))$
14	13	baibd	$⊢ ((A \subseteq ℂ \land x \in A) \land F : A ⟶ ℂ) \to (F \in ((TopOpen (ℂ_{fld}) ↾_{𝑡} A) CnP TopOpen (ℂ_{fld})) (x) \leftrightarrow F (x) \in (F {lim}_{ℂ} x))$
15	14	an32s	$⊢ ((A \subseteq ℂ \land F : A ⟶ ℂ) \land x \in A) \to (F \in ((TopOpen (ℂ_{fld}) ↾_{𝑡} A) CnP TopOpen (ℂ_{fld})) (x) \leftrightarrow F (x) \in (F {lim}_{ℂ} x))$
16	15	ralbidva	$⊢ (A \subseteq ℂ \land F : A ⟶ ℂ) \to (\forall x \in A F \in ((TopOpen (ℂ_{fld}) ↾_{𝑡} A) CnP TopOpen (ℂ_{fld})) (x) \leftrightarrow \forall x \in A F (x) \in (F {lim}_{ℂ} x))$
17	16	pm5.32da	$⊢ A \subseteq ℂ \to ((F : A ⟶ ℂ \land \forall x \in A F \in ((TopOpen (ℂ_{fld}) ↾_{𝑡} A) CnP TopOpen (ℂ_{fld})) (x)) \leftrightarrow (F : A ⟶ ℂ \land \forall x \in A F (x) \in (F {lim}_{ℂ} x)))$
18	8 12 17	3bitrd	$⊢ A \subseteq ℂ \to (F : A \underset{cn}{⟶} ℂ \leftrightarrow (F : A ⟶ ℂ \land \forall x \in A F (x) \in (F {lim}_{ℂ} x)))$