dlatmjdi

Description: In a distributive lattice, meets distribute over joins. (Contributed by Stefan O'Rear, 30-Jan-2015)

	Ref	Expression
Hypotheses	isdlat.b	$⊢ B = {Base}_{K}$
	isdlat.j	$⊢ \underset{˙}{\lor} = join (K)$
	isdlat.m	$⊢ \underset{˙}{\land} = meet (K)$
Assertion	dlatmjdi	$⊢ (K \in DLat \land (X \in B \land Y \in B \land Z \in B)) \to X \underset{˙}{\land} (Y \underset{˙}{\lor} Z) = (X \underset{˙}{\land} Y) \underset{˙}{\lor} (X \underset{˙}{\land} Z)$

Proof

Step	Hyp	Ref	Expression
1		isdlat.b	$⊢ B = {Base}_{K}$
2		isdlat.j	$⊢ \underset{˙}{\lor} = join (K)$
3		isdlat.m	$⊢ \underset{˙}{\land} = meet (K)$
4	1 2 3	isdlat	$⊢ K \in DLat \leftrightarrow (K \in Lat \land \forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\land} (y \underset{˙}{\lor} z) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} z))$
5	4	simprbi	$⊢ K \in DLat \to \forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\land} (y \underset{˙}{\lor} z) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} z)$
6		oveq1	$⊢ x = X \to x \underset{˙}{\land} (y \underset{˙}{\lor} z) = X \underset{˙}{\land} (y \underset{˙}{\lor} z)$
7		oveq1	$⊢ x = X \to x \underset{˙}{\land} y = X \underset{˙}{\land} y$
8		oveq1	$⊢ x = X \to x \underset{˙}{\land} z = X \underset{˙}{\land} z$
9	7 8	oveq12d	$⊢ x = X \to (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} z) = (X \underset{˙}{\land} y) \underset{˙}{\lor} (X \underset{˙}{\land} z)$
10	6 9	eqeq12d	$⊢ x = X \to (x \underset{˙}{\land} (y \underset{˙}{\lor} z) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} z) \leftrightarrow X \underset{˙}{\land} (y \underset{˙}{\lor} z) = (X \underset{˙}{\land} y) \underset{˙}{\lor} (X \underset{˙}{\land} z))$
11		oveq1	$⊢ y = Y \to y \underset{˙}{\lor} z = Y \underset{˙}{\lor} z$
12	11	oveq2d	$⊢ y = Y \to X \underset{˙}{\land} (y \underset{˙}{\lor} z) = X \underset{˙}{\land} (Y \underset{˙}{\lor} z)$
13		oveq2	$⊢ y = Y \to X \underset{˙}{\land} y = X \underset{˙}{\land} Y$
14	13	oveq1d	$⊢ y = Y \to (X \underset{˙}{\land} y) \underset{˙}{\lor} (X \underset{˙}{\land} z) = (X \underset{˙}{\land} Y) \underset{˙}{\lor} (X \underset{˙}{\land} z)$
15	12 14	eqeq12d	$⊢ y = Y \to (X \underset{˙}{\land} (y \underset{˙}{\lor} z) = (X \underset{˙}{\land} y) \underset{˙}{\lor} (X \underset{˙}{\land} z) \leftrightarrow X \underset{˙}{\land} (Y \underset{˙}{\lor} z) = (X \underset{˙}{\land} Y) \underset{˙}{\lor} (X \underset{˙}{\land} z))$
16		oveq2	$⊢ z = Z \to Y \underset{˙}{\lor} z = Y \underset{˙}{\lor} Z$
17	16	oveq2d	$⊢ z = Z \to X \underset{˙}{\land} (Y \underset{˙}{\lor} z) = X \underset{˙}{\land} (Y \underset{˙}{\lor} Z)$
18		oveq2	$⊢ z = Z \to X \underset{˙}{\land} z = X \underset{˙}{\land} Z$
19	18	oveq2d	$⊢ z = Z \to (X \underset{˙}{\land} Y) \underset{˙}{\lor} (X \underset{˙}{\land} z) = (X \underset{˙}{\land} Y) \underset{˙}{\lor} (X \underset{˙}{\land} Z)$
20	17 19	eqeq12d	$⊢ z = Z \to (X \underset{˙}{\land} (Y \underset{˙}{\lor} z) = (X \underset{˙}{\land} Y) \underset{˙}{\lor} (X \underset{˙}{\land} z) \leftrightarrow X \underset{˙}{\land} (Y \underset{˙}{\lor} Z) = (X \underset{˙}{\land} Y) \underset{˙}{\lor} (X \underset{˙}{\land} Z))$
21	10 15 20	rspc3v	$⊢ (X \in B \land Y \in B \land Z \in B) \to (\forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\land} (y \underset{˙}{\lor} z) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} z) \to X \underset{˙}{\land} (Y \underset{˙}{\lor} Z) = (X \underset{˙}{\land} Y) \underset{˙}{\lor} (X \underset{˙}{\land} Z))$
22	5 21	mpan9	$⊢ (K \in DLat \land (X \in B \land Y \in B \land Z \in B)) \to X \underset{˙}{\land} (Y \underset{˙}{\lor} Z) = (X \underset{˙}{\land} Y) \underset{˙}{\lor} (X \underset{˙}{\land} Z)$

Metamath Proof Explorer

Theorem dlatmjdi

Proof