omlsii

Description: Subspace inference form of orthomodular law in the Hilbert lattice. (Contributed by NM, 14-Oct-1999) (Revised by Mario Carneiro, 15-May-2014) (New usage is discouraged.)

	Ref	Expression
Hypotheses	omlsi.1	$⊢ A \in C_{ℋ}$
	omlsi.2	$⊢ B \in S_{ℋ}$
	omlsi.3	$⊢ A \subseteq B$
	omlsi.4	$⊢ B \cap ⊥ (A) = 0_{ℋ}$
Assertion	omlsii	$⊢ A = B$

Proof

Step	Hyp	Ref	Expression
1		omlsi.1	$⊢ A \in C_{ℋ}$
2		omlsi.2	$⊢ B \in S_{ℋ}$
3		omlsi.3	$⊢ A \subseteq B$
4		omlsi.4	$⊢ B \cap ⊥ (A) = 0_{ℋ}$
5	2	sheli	$⊢ x \in B \to x \in ℋ$
6	1 5	pjhthlem2	$⊢ x \in B \to \exists y \in A \exists z \in ⊥ (A) x = y +_{ℎ} z$
7		eqeq1	$⊢ x = if (x \in B, x, 0_{ℎ}) \to (x = y +_{ℎ} z \leftrightarrow if (x \in B, x, 0_{ℎ}) = y +_{ℎ} z)$
8		eleq1	$⊢ x = if (x \in B, x, 0_{ℎ}) \to (x \in A \leftrightarrow if (x \in B, x, 0_{ℎ}) \in A)$
9	7 8	imbi12d	$⊢ x = if (x \in B, x, 0_{ℎ}) \to ((x = y +_{ℎ} z \to x \in A) \leftrightarrow (if (x \in B, x, 0_{ℎ}) = y +_{ℎ} z \to if (x \in B, x, 0_{ℎ}) \in A))$
10		oveq1	$⊢ y = if (y \in A, y, 0_{ℎ}) \to y +_{ℎ} z = if (y \in A, y, 0_{ℎ}) +_{ℎ} z$
11	10	eqeq2d	$⊢ y = if (y \in A, y, 0_{ℎ}) \to (if (x \in B, x, 0_{ℎ}) = y +_{ℎ} z \leftrightarrow if (x \in B, x, 0_{ℎ}) = if (y \in A, y, 0_{ℎ}) +_{ℎ} z)$
12	11	imbi1d	$⊢ y = if (y \in A, y, 0_{ℎ}) \to ((if (x \in B, x, 0_{ℎ}) = y +_{ℎ} z \to if (x \in B, x, 0_{ℎ}) \in A) \leftrightarrow (if (x \in B, x, 0_{ℎ}) = if (y \in A, y, 0_{ℎ}) +_{ℎ} z \to if (x \in B, x, 0_{ℎ}) \in A))$
13		oveq2	$⊢ z = if (z \in ⊥ (A), z, 0_{ℎ}) \to if (y \in A, y, 0_{ℎ}) +_{ℎ} z = if (y \in A, y, 0_{ℎ}) +_{ℎ} if (z \in ⊥ (A), z, 0_{ℎ})$
14	13	eqeq2d	$⊢ z = if (z \in ⊥ (A), z, 0_{ℎ}) \to (if (x \in B, x, 0_{ℎ}) = if (y \in A, y, 0_{ℎ}) +_{ℎ} z \leftrightarrow if (x \in B, x, 0_{ℎ}) = if (y \in A, y, 0_{ℎ}) +_{ℎ} if (z \in ⊥ (A), z, 0_{ℎ}))$
15	14	imbi1d	$⊢ z = if (z \in ⊥ (A), z, 0_{ℎ}) \to ((if (x \in B, x, 0_{ℎ}) = if (y \in A, y, 0_{ℎ}) +_{ℎ} z \to if (x \in B, x, 0_{ℎ}) \in A) \leftrightarrow (if (x \in B, x, 0_{ℎ}) = if (y \in A, y, 0_{ℎ}) +_{ℎ} if (z \in ⊥ (A), z, 0_{ℎ}) \to if (x \in B, x, 0_{ℎ}) \in A))$
16	1	chshii	$⊢ A \in S_{ℋ}$
17		sh0	$⊢ B \in S_{ℋ} \to 0_{ℎ} \in B$
18	2 17	ax-mp	$⊢ 0_{ℎ} \in B$
19	18	elimel	$⊢ if (x \in B, x, 0_{ℎ}) \in B$
20		ch0	$⊢ A \in C_{ℋ} \to 0_{ℎ} \in A$
21	1 20	ax-mp	$⊢ 0_{ℎ} \in A$
22	21	elimel	$⊢ if (y \in A, y, 0_{ℎ}) \in A$
23		shocsh	$⊢ A \in S_{ℋ} \to ⊥ (A) \in S_{ℋ}$
24	16 23	ax-mp	$⊢ ⊥ (A) \in S_{ℋ}$
25		sh0	$⊢ ⊥ (A) \in S_{ℋ} \to 0_{ℎ} \in ⊥ (A)$
26	24 25	ax-mp	$⊢ 0_{ℎ} \in ⊥ (A)$
27	26	elimel	$⊢ if (z \in ⊥ (A), z, 0_{ℎ}) \in ⊥ (A)$
28	16 2 3 4 19 22 27	omlsilem	$⊢ if (x \in B, x, 0_{ℎ}) = if (y \in A, y, 0_{ℎ}) +_{ℎ} if (z \in ⊥ (A), z, 0_{ℎ}) \to if (x \in B, x, 0_{ℎ}) \in A$
29	9 12 15 28	dedth3h	$⊢ (x \in B \land y \in A \land z \in ⊥ (A)) \to (x = y +_{ℎ} z \to x \in A)$
30	29	3expia	$⊢ (x \in B \land y \in A) \to (z \in ⊥ (A) \to (x = y +_{ℎ} z \to x \in A))$
31	30	rexlimdv	$⊢ (x \in B \land y \in A) \to (\exists z \in ⊥ (A) x = y +_{ℎ} z \to x \in A)$
32	31	rexlimdva	$⊢ x \in B \to (\exists y \in A \exists z \in ⊥ (A) x = y +_{ℎ} z \to x \in A)$
33	6 32	mpd	$⊢ x \in B \to x \in A$
34	33	ssriv	$⊢ B \subseteq A$
35	3 34	eqssi	$⊢ A = B$

Metamath Proof Explorer

Theorem omlsii

Proof