cvbr

Description: Binary relation expressing B covers A , which means that B is larger than A and there is nothing in between. Definition 3.2.18 of PtakPulmannova p. 68. (Contributed by NM, 4-Jun-2004) (New usage is discouraged.)

		Ref	Expression
	Assertion	cvbr	$⊢ (A \in C_{ℋ} \land B \in C_{ℋ}) \to (A ⋖_{ℋ} B \leftrightarrow (A \subset B \land \neg \exists x \in C_{ℋ} (A \subset x \land x \subset B)))$

Proof

Step	Hyp	Ref	Expression
1		eleq1	$⊢ y = A \to (y \in C_{ℋ} \leftrightarrow A \in C_{ℋ})$
2	1	anbi1d	$⊢ y = A \to ((y \in C_{ℋ} \land z \in C_{ℋ}) \leftrightarrow (A \in C_{ℋ} \land z \in C_{ℋ}))$
3		psseq1	$⊢ y = A \to (y \subset z \leftrightarrow A \subset z)$
4		psseq1	$⊢ y = A \to (y \subset x \leftrightarrow A \subset x)$
5	4	anbi1d	$⊢ y = A \to ((y \subset x \land x \subset z) \leftrightarrow (A \subset x \land x \subset z))$
6	5	rexbidv	$⊢ y = A \to (\exists x \in C_{ℋ} (y \subset x \land x \subset z) \leftrightarrow \exists x \in C_{ℋ} (A \subset x \land x \subset z))$
7	6	notbid	$⊢ y = A \to (\neg \exists x \in C_{ℋ} (y \subset x \land x \subset z) \leftrightarrow \neg \exists x \in C_{ℋ} (A \subset x \land x \subset z))$
8	3 7	anbi12d	$⊢ y = A \to ((y \subset z \land \neg \exists x \in C_{ℋ} (y \subset x \land x \subset z)) \leftrightarrow (A \subset z \land \neg \exists x \in C_{ℋ} (A \subset x \land x \subset z)))$
9	2 8	anbi12d	$⊢ y = A \to (((y \in C_{ℋ} \land z \in C_{ℋ}) \land (y \subset z \land \neg \exists x \in C_{ℋ} (y \subset x \land x \subset z))) \leftrightarrow ((A \in C_{ℋ} \land z \in C_{ℋ}) \land (A \subset z \land \neg \exists x \in C_{ℋ} (A \subset x \land x \subset z))))$
10		eleq1	$⊢ z = B \to (z \in C_{ℋ} \leftrightarrow B \in C_{ℋ})$
11	10	anbi2d	$⊢ z = B \to ((A \in C_{ℋ} \land z \in C_{ℋ}) \leftrightarrow (A \in C_{ℋ} \land B \in C_{ℋ}))$
12		psseq2	$⊢ z = B \to (A \subset z \leftrightarrow A \subset B)$
13		psseq2	$⊢ z = B \to (x \subset z \leftrightarrow x \subset B)$
14	13	anbi2d	$⊢ z = B \to ((A \subset x \land x \subset z) \leftrightarrow (A \subset x \land x \subset B))$
15	14	rexbidv	$⊢ z = B \to (\exists x \in C_{ℋ} (A \subset x \land x \subset z) \leftrightarrow \exists x \in C_{ℋ} (A \subset x \land x \subset B))$
16	15	notbid	$⊢ z = B \to (\neg \exists x \in C_{ℋ} (A \subset x \land x \subset z) \leftrightarrow \neg \exists x \in C_{ℋ} (A \subset x \land x \subset B))$
17	12 16	anbi12d	$⊢ z = B \to ((A \subset z \land \neg \exists x \in C_{ℋ} (A \subset x \land x \subset z)) \leftrightarrow (A \subset B \land \neg \exists x \in C_{ℋ} (A \subset x \land x \subset B)))$
18	11 17	anbi12d	$⊢ z = B \to (((A \in C_{ℋ} \land z \in C_{ℋ}) \land (A \subset z \land \neg \exists x \in C_{ℋ} (A \subset x \land x \subset z))) \leftrightarrow ((A \in C_{ℋ} \land B \in C_{ℋ}) \land (A \subset B \land \neg \exists x \in C_{ℋ} (A \subset x \land x \subset B))))$
19		df-cv	$⊢ ⋖_{ℋ} = \{⟨y, z⟩ \| ((y \in C_{ℋ} \land z \in C_{ℋ}) \land (y \subset z \land \neg \exists x \in C_{ℋ} (y \subset x \land x \subset z)))\}$
20	9 18 19	brabg	$⊢ (A \in C_{ℋ} \land B \in C_{ℋ}) \to (A ⋖_{ℋ} B \leftrightarrow ((A \in C_{ℋ} \land B \in C_{ℋ}) \land (A \subset B \land \neg \exists x \in C_{ℋ} (A \subset x \land x \subset B))))$
21	20	bianabs	$⊢ (A \in C_{ℋ} \land B \in C_{ℋ}) \to (A ⋖_{ℋ} B \leftrightarrow (A \subset B \land \neg \exists x \in C_{ℋ} (A \subset x \land x \subset B)))$

Metamath Proof Explorer

Theorem cvbr

Proof