disjtp2

Description: Two completely distinct unordered triples are disjoint. (Contributed by AV, 14-Nov-2021)

		Ref	Expression
	Assertion	disjtp2	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( { A , B , C } i^i { D , E , F } ) = (/) )

Proof

Step	Hyp	Ref	Expression
1		df-tp	\|- { D , E , F } = ( { D , E } u. { F } )
2	1	ineq2i	\|- ( { A , B , C } i^i { D , E , F } ) = ( { A , B , C } i^i ( { D , E } u. { F } ) )
3		df-tp	\|- { A , B , C } = ( { A , B } u. { C } )
4	3	ineq1i	\|- ( { A , B , C } i^i { D , E } ) = ( ( { A , B } u. { C } ) i^i { D , E } )
5		3simpa	\|- ( ( A =/= D /\ B =/= D /\ C =/= D ) -> ( A =/= D /\ B =/= D ) )
6		3simpa	\|- ( ( A =/= E /\ B =/= E /\ C =/= E ) -> ( A =/= E /\ B =/= E ) )
7		disjpr2	\|- ( ( ( A =/= D /\ B =/= D ) /\ ( A =/= E /\ B =/= E ) ) -> ( { A , B } i^i { D , E } ) = (/) )
8	5 6 7	syl2an	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) ) -> ( { A , B } i^i { D , E } ) = (/) )
9	8	3adant3	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( { A , B } i^i { D , E } ) = (/) )
10		incom	\|- ( { C } i^i { D , E } ) = ( { D , E } i^i { C } )
11		necom	\|- ( C =/= D <-> D =/= C )
12	11	biimpi	\|- ( C =/= D -> D =/= C )
13	12	3ad2ant3	\|- ( ( A =/= D /\ B =/= D /\ C =/= D ) -> D =/= C )
14		necom	\|- ( C =/= E <-> E =/= C )
15	14	biimpi	\|- ( C =/= E -> E =/= C )
16	15	3ad2ant3	\|- ( ( A =/= E /\ B =/= E /\ C =/= E ) -> E =/= C )
17		disjprsn	\|- ( ( D =/= C /\ E =/= C ) -> ( { D , E } i^i { C } ) = (/) )
18	13 16 17	syl2an	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) ) -> ( { D , E } i^i { C } ) = (/) )
19	18	3adant3	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( { D , E } i^i { C } ) = (/) )
20	10 19	syl5eq	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( { C } i^i { D , E } ) = (/) )
21	9 20	jca	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( ( { A , B } i^i { D , E } ) = (/) /\ ( { C } i^i { D , E } ) = (/) ) )
22		undisj1	\|- ( ( ( { A , B } i^i { D , E } ) = (/) /\ ( { C } i^i { D , E } ) = (/) ) <-> ( ( { A , B } u. { C } ) i^i { D , E } ) = (/) )
23	21 22	sylib	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( ( { A , B } u. { C } ) i^i { D , E } ) = (/) )
24	4 23	syl5eq	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( { A , B , C } i^i { D , E } ) = (/) )
25		disjtpsn	\|- ( ( A =/= F /\ B =/= F /\ C =/= F ) -> ( { A , B , C } i^i { F } ) = (/) )
26	25	3ad2ant3	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( { A , B , C } i^i { F } ) = (/) )
27	24 26	jca	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( ( { A , B , C } i^i { D , E } ) = (/) /\ ( { A , B , C } i^i { F } ) = (/) ) )
28		undisj2	\|- ( ( ( { A , B , C } i^i { D , E } ) = (/) /\ ( { A , B , C } i^i { F } ) = (/) ) <-> ( { A , B , C } i^i ( { D , E } u. { F } ) ) = (/) )
29	27 28	sylib	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( { A , B , C } i^i ( { D , E } u. { F } ) ) = (/) )
30	2 29	syl5eq	\|- ( ( ( A =/= D /\ B =/= D /\ C =/= D ) /\ ( A =/= E /\ B =/= E /\ C =/= E ) /\ ( A =/= F /\ B =/= F /\ C =/= F ) ) -> ( { A , B , C } i^i { D , E , F } ) = (/) )

Metamath Proof Explorer

Theorem disjtp2

Proof