latdisd

Description: In a lattice, joins distribute over meets if and only if meets distribute over joins; the distributive property is self-dual. (Contributed by Stefan O'Rear, 29-Jan-2015)

	Ref	Expression
Hypotheses	latdisd.b	$⊢ B = {Base}_{K}$
	latdisd.j	$⊢ \underset{˙}{\lor} = join (K)$
	latdisd.m	$⊢ \underset{˙}{\land} = meet (K)$
Assertion	latdisd	$⊢ K \in Lat \to (\forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\lor} (y \underset{˙}{\land} z) = (x \underset{˙}{\lor} y) \underset{˙}{\land} (x \underset{˙}{\lor} z) \leftrightarrow \forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\land} (y \underset{˙}{\lor} z) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} z))$

Proof

Step	Hyp	Ref	Expression
1		latdisd.b	$⊢ B = {Base}_{K}$
2		latdisd.j	$⊢ \underset{˙}{\lor} = join (K)$
3		latdisd.m	$⊢ \underset{˙}{\land} = meet (K)$
4	1 2 3	latdisdlem	$⊢ K \in Lat \to (\forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\lor} (y \underset{˙}{\land} z) = (x \underset{˙}{\lor} y) \underset{˙}{\land} (x \underset{˙}{\lor} z) \to \forall u \in B \forall v \in B \forall w \in B u \underset{˙}{\land} (v \underset{˙}{\lor} w) = (u \underset{˙}{\land} v) \underset{˙}{\lor} (u \underset{˙}{\land} w))$
5		eqid	$⊢ ODual (K) = ODual (K)$
6	5	odulat	$⊢ K \in Lat \to ODual (K) \in Lat$
7	5 1	odubas	$⊢ B = {Base}_{ODual (K)}$
8	5 3	odujoin	$⊢ \underset{˙}{\land} = join (ODual (K))$
9	5 2	odumeet	$⊢ \underset{˙}{\lor} = meet (ODual (K))$
10	7 8 9	latdisdlem	$⊢ ODual (K) \in Lat \to (\forall u \in B \forall v \in B \forall w \in B u \underset{˙}{\land} (v \underset{˙}{\lor} w) = (u \underset{˙}{\land} v) \underset{˙}{\lor} (u \underset{˙}{\land} w) \to \forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\lor} (y \underset{˙}{\land} z) = (x \underset{˙}{\lor} y) \underset{˙}{\land} (x \underset{˙}{\lor} z))$
11	6 10	syl	$⊢ K \in Lat \to (\forall u \in B \forall v \in B \forall w \in B u \underset{˙}{\land} (v \underset{˙}{\lor} w) = (u \underset{˙}{\land} v) \underset{˙}{\lor} (u \underset{˙}{\land} w) \to \forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\lor} (y \underset{˙}{\land} z) = (x \underset{˙}{\lor} y) \underset{˙}{\land} (x \underset{˙}{\lor} z))$
12	4 11	impbid	$⊢ K \in Lat \to (\forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\lor} (y \underset{˙}{\land} z) = (x \underset{˙}{\lor} y) \underset{˙}{\land} (x \underset{˙}{\lor} z) \leftrightarrow \forall u \in B \forall v \in B \forall w \in B u \underset{˙}{\land} (v \underset{˙}{\lor} w) = (u \underset{˙}{\land} v) \underset{˙}{\lor} (u \underset{˙}{\land} w))$
13		oveq1	$⊢ u = x \to u \underset{˙}{\land} (v \underset{˙}{\lor} w) = x \underset{˙}{\land} (v \underset{˙}{\lor} w)$
14		oveq1	$⊢ u = x \to u \underset{˙}{\land} v = x \underset{˙}{\land} v$
15		oveq1	$⊢ u = x \to u \underset{˙}{\land} w = x \underset{˙}{\land} w$
16	14 15	oveq12d	$⊢ u = x \to (u \underset{˙}{\land} v) \underset{˙}{\lor} (u \underset{˙}{\land} w) = (x \underset{˙}{\land} v) \underset{˙}{\lor} (x \underset{˙}{\land} w)$
17	13 16	eqeq12d	$⊢ u = x \to (u \underset{˙}{\land} (v \underset{˙}{\lor} w) = (u \underset{˙}{\land} v) \underset{˙}{\lor} (u \underset{˙}{\land} w) \leftrightarrow x \underset{˙}{\land} (v \underset{˙}{\lor} w) = (x \underset{˙}{\land} v) \underset{˙}{\lor} (x \underset{˙}{\land} w))$
18		oveq1	$⊢ v = y \to v \underset{˙}{\lor} w = y \underset{˙}{\lor} w$
19	18	oveq2d	$⊢ v = y \to x \underset{˙}{\land} (v \underset{˙}{\lor} w) = x \underset{˙}{\land} (y \underset{˙}{\lor} w)$
20		oveq2	$⊢ v = y \to x \underset{˙}{\land} v = x \underset{˙}{\land} y$
21	20	oveq1d	$⊢ v = y \to (x \underset{˙}{\land} v) \underset{˙}{\lor} (x \underset{˙}{\land} w) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} w)$
22	19 21	eqeq12d	$⊢ v = y \to (x \underset{˙}{\land} (v \underset{˙}{\lor} w) = (x \underset{˙}{\land} v) \underset{˙}{\lor} (x \underset{˙}{\land} w) \leftrightarrow x \underset{˙}{\land} (y \underset{˙}{\lor} w) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} w))$
23		oveq2	$⊢ w = z \to y \underset{˙}{\lor} w = y \underset{˙}{\lor} z$
24	23	oveq2d	$⊢ w = z \to x \underset{˙}{\land} (y \underset{˙}{\lor} w) = x \underset{˙}{\land} (y \underset{˙}{\lor} z)$
25		oveq2	$⊢ w = z \to x \underset{˙}{\land} w = x \underset{˙}{\land} z$
26	25	oveq2d	$⊢ w = z \to (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} w) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} z)$
27	24 26	eqeq12d	$⊢ w = z \to (x \underset{˙}{\land} (y \underset{˙}{\lor} w) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} w) \leftrightarrow x \underset{˙}{\land} (y \underset{˙}{\lor} z) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} z))$
28	17 22 27	cbvral3vw	$⊢ \forall u \in B \forall v \in B \forall w \in B u \underset{˙}{\land} (v \underset{˙}{\lor} w) = (u \underset{˙}{\land} v) \underset{˙}{\lor} (u \underset{˙}{\land} w) \leftrightarrow \forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\land} (y \underset{˙}{\lor} z) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} z)$
29	12 28	bitrdi	$⊢ K \in Lat \to (\forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\lor} (y \underset{˙}{\land} z) = (x \underset{˙}{\lor} y) \underset{˙}{\land} (x \underset{˙}{\lor} z) \leftrightarrow \forall x \in B \forall y \in B \forall z \in B x \underset{˙}{\land} (y \underset{˙}{\lor} z) = (x \underset{˙}{\land} y) \underset{˙}{\lor} (x \underset{˙}{\land} z))$

Metamath Proof Explorer

Theorem latdisd

Proof