lsmdisj2b

Description: Association of the disjointness constraint in a subgroup sum. (Contributed by Mario Carneiro, 21-Apr-2016)

	Ref	Expression
Hypotheses	lsmcntz.p	$⊢ \underset{˙}{\oplus} = LSSum (G)$
	lsmcntz.s	$⊢ φ \to S \in SubGrp (G)$
	lsmcntz.t	$⊢ φ \to T \in SubGrp (G)$
	lsmcntz.u	$⊢ φ \to U \in SubGrp (G)$
	lsmdisj.o	$⊢ \underset{˙}{0} = 0_{G}$
Assertion	lsmdisj2b	$⊢ φ \to (((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\}) \leftrightarrow (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\}))$

Proof

Step	Hyp	Ref	Expression
1		lsmcntz.p	$⊢ \underset{˙}{\oplus} = LSSum (G)$
2		lsmcntz.s	$⊢ φ \to S \in SubGrp (G)$
3		lsmcntz.t	$⊢ φ \to T \in SubGrp (G)$
4		lsmcntz.u	$⊢ φ \to U \in SubGrp (G)$
5		lsmdisj.o	$⊢ \underset{˙}{0} = 0_{G}$
6		incom	$⊢ S \cap (T \underset{˙}{\oplus} U) = (T \underset{˙}{\oplus} U) \cap S$
7	3	adantr	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to T \in SubGrp (G)$
8	2	adantr	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to S \in SubGrp (G)$
9	4	adantr	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to U \in SubGrp (G)$
10		incom	$⊢ T \cap (S \underset{˙}{\oplus} U) = (S \underset{˙}{\oplus} U) \cap T$
11		simprl	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to (S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\}$
12	10 11	syl5eq	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to T \cap (S \underset{˙}{\oplus} U) = \{\underset{˙}{0}\}$
13		simprr	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to S \cap U = \{\underset{˙}{0}\}$
14	1 7 8 9 5 12 13	lsmdisj2r	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to (T \underset{˙}{\oplus} U) \cap S = \{\underset{˙}{0}\}$
15	6 14	syl5eq	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\}$
16		incom	$⊢ T \cap U = U \cap T$
17	1 8 9 7 5 11	lsmdisj	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to (S \cap T = \{\underset{˙}{0}\} \land U \cap T = \{\underset{˙}{0}\})$
18	17	simprd	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to U \cap T = \{\underset{˙}{0}\}$
19	16 18	syl5eq	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to T \cap U = \{\underset{˙}{0}\}$
20	15 19	jca	$⊢ (φ \land ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})) \to (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\})$
21	2	adantr	$⊢ (φ \land (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\})) \to S \in SubGrp (G)$
22	3	adantr	$⊢ (φ \land (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\})) \to T \in SubGrp (G)$
23	4	adantr	$⊢ (φ \land (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\})) \to U \in SubGrp (G)$
24		simprl	$⊢ (φ \land (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\})) \to S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\}$
25		simprr	$⊢ (φ \land (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\})) \to T \cap U = \{\underset{˙}{0}\}$
26	1 21 22 23 5 24 25	lsmdisj2r	$⊢ (φ \land (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\})) \to (S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\}$
27	1 21 22 23 5 24	lsmdisjr	$⊢ (φ \land (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\})) \to (S \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})$
28	27	simprd	$⊢ (φ \land (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\})) \to S \cap U = \{\underset{˙}{0}\}$
29	26 28	jca	$⊢ (φ \land (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\})) \to ((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\})$
30	20 29	impbida	$⊢ φ \to (((S \underset{˙}{\oplus} U) \cap T = \{\underset{˙}{0}\} \land S \cap U = \{\underset{˙}{0}\}) \leftrightarrow (S \cap (T \underset{˙}{\oplus} U) = \{\underset{˙}{0}\} \land T \cap U = \{\underset{˙}{0}\}))$

Metamath Proof Explorer

Theorem lsmdisj2b

Proof