fiin

Description: The elements of ( fiC ) are closed under finite intersection. (Contributed by Mario Carneiro, 24-Nov-2013)

		Ref	Expression
	Assertion	fiin	$⊢ (A \in fi (C) \land B \in fi (C)) \to A \cap B \in fi (C)$

Proof

Step	Hyp	Ref	Expression
1		elfvex	$⊢ A \in fi (C) \to C \in V$
2		elfi	$⊢ (A \in fi (C) \land C \in V) \to (A \in fi (C) \leftrightarrow \exists x \in (𝒫 C \cap Fin) A = ⋂ x)$
3	1 2	mpdan	$⊢ A \in fi (C) \to (A \in fi (C) \leftrightarrow \exists x \in (𝒫 C \cap Fin) A = ⋂ x)$
4	3	ibi	$⊢ A \in fi (C) \to \exists x \in (𝒫 C \cap Fin) A = ⋂ x$
5	4	adantr	$⊢ (A \in fi (C) \land B \in fi (C)) \to \exists x \in (𝒫 C \cap Fin) A = ⋂ x$
6		simpr	$⊢ (A \in fi (C) \land B \in fi (C)) \to B \in fi (C)$
7		elfi	$⊢ (B \in fi (C) \land C \in V) \to (B \in fi (C) \leftrightarrow \exists y \in (𝒫 C \cap Fin) B = ⋂ y)$
8	7	ancoms	$⊢ (C \in V \land B \in fi (C)) \to (B \in fi (C) \leftrightarrow \exists y \in (𝒫 C \cap Fin) B = ⋂ y)$
9	1 8	sylan	$⊢ (A \in fi (C) \land B \in fi (C)) \to (B \in fi (C) \leftrightarrow \exists y \in (𝒫 C \cap Fin) B = ⋂ y)$
10	6 9	mpbid	$⊢ (A \in fi (C) \land B \in fi (C)) \to \exists y \in (𝒫 C \cap Fin) B = ⋂ y$
11		elin	$⊢ x \in (𝒫 C \cap Fin) \leftrightarrow (x \in 𝒫 C \land x \in Fin)$
12		elin	$⊢ y \in (𝒫 C \cap Fin) \leftrightarrow (y \in 𝒫 C \land y \in Fin)$
13		pwuncl	$⊢ (x \in 𝒫 C \land y \in 𝒫 C) \to x \cup y \in 𝒫 C$
14		unfi	$⊢ (x \in Fin \land y \in Fin) \to x \cup y \in Fin$
15	13 14	anim12i	$⊢ ((x \in 𝒫 C \land y \in 𝒫 C) \land (x \in Fin \land y \in Fin)) \to (x \cup y \in 𝒫 C \land x \cup y \in Fin)$
16	15	an4s	$⊢ ((x \in 𝒫 C \land x \in Fin) \land (y \in 𝒫 C \land y \in Fin)) \to (x \cup y \in 𝒫 C \land x \cup y \in Fin)$
17	11 12 16	syl2anb	$⊢ (x \in (𝒫 C \cap Fin) \land y \in (𝒫 C \cap Fin)) \to (x \cup y \in 𝒫 C \land x \cup y \in Fin)$
18		elin	$⊢ x \cup y \in (𝒫 C \cap Fin) \leftrightarrow (x \cup y \in 𝒫 C \land x \cup y \in Fin)$
19	17 18	sylibr	$⊢ (x \in (𝒫 C \cap Fin) \land y \in (𝒫 C \cap Fin)) \to x \cup y \in (𝒫 C \cap Fin)$
20		ineq12	$⊢ (A = ⋂ x \land B = ⋂ y) \to A \cap B = ⋂ x \cap ⋂ y$
21		intun	$⊢ ⋂ (x \cup y) = ⋂ x \cap ⋂ y$
22	20 21	eqtr4di	$⊢ (A = ⋂ x \land B = ⋂ y) \to A \cap B = ⋂ (x \cup y)$
23		inteq	$⊢ z = x \cup y \to ⋂ z = ⋂ (x \cup y)$
24	23	rspceeqv	$⊢ (x \cup y \in (𝒫 C \cap Fin) \land A \cap B = ⋂ (x \cup y)) \to \exists z \in (𝒫 C \cap Fin) A \cap B = ⋂ z$
25	19 22 24	syl2an	$⊢ ((x \in (𝒫 C \cap Fin) \land y \in (𝒫 C \cap Fin)) \land (A = ⋂ x \land B = ⋂ y)) \to \exists z \in (𝒫 C \cap Fin) A \cap B = ⋂ z$
26	25	an4s	$⊢ ((x \in (𝒫 C \cap Fin) \land A = ⋂ x) \land (y \in (𝒫 C \cap Fin) \land B = ⋂ y)) \to \exists z \in (𝒫 C \cap Fin) A \cap B = ⋂ z$
27	26	rexlimdvaa	$⊢ (x \in (𝒫 C \cap Fin) \land A = ⋂ x) \to (\exists y \in (𝒫 C \cap Fin) B = ⋂ y \to \exists z \in (𝒫 C \cap Fin) A \cap B = ⋂ z)$
28	27	rexlimiva	$⊢ \exists x \in (𝒫 C \cap Fin) A = ⋂ x \to (\exists y \in (𝒫 C \cap Fin) B = ⋂ y \to \exists z \in (𝒫 C \cap Fin) A \cap B = ⋂ z)$
29	5 10 28	sylc	$⊢ (A \in fi (C) \land B \in fi (C)) \to \exists z \in (𝒫 C \cap Fin) A \cap B = ⋂ z$
30		inex1g	$⊢ A \in fi (C) \to A \cap B \in V$
31		elfi	$⊢ (A \cap B \in V \land C \in V) \to (A \cap B \in fi (C) \leftrightarrow \exists z \in (𝒫 C \cap Fin) A \cap B = ⋂ z)$
32	30 1 31	syl2anc	$⊢ A \in fi (C) \to (A \cap B \in fi (C) \leftrightarrow \exists z \in (𝒫 C \cap Fin) A \cap B = ⋂ z)$
33	32	adantr	$⊢ (A \in fi (C) \land B \in fi (C)) \to (A \cap B \in fi (C) \leftrightarrow \exists z \in (𝒫 C \cap Fin) A \cap B = ⋂ z)$
34	29 33	mpbird	$⊢ (A \in fi (C) \land B \in fi (C)) \to A \cap B \in fi (C)$

Metamath Proof Explorer

Theorem fiin

Proof