xpcan

Description: Cancellation law for Cartesian product. (Contributed by NM, 30-Aug-2011)

		Ref	Expression
	Assertion	xpcan	\|- ( C =/= (/) -> ( ( C X. A ) = ( C X. B ) <-> A = B ) )

Proof

Step	Hyp	Ref	Expression
1		xp11	\|- ( ( C =/= (/) /\ A =/= (/) ) -> ( ( C X. A ) = ( C X. B ) <-> ( C = C /\ A = B ) ) )
2		eqid	\|- C = C
3	2	biantrur	\|- ( A = B <-> ( C = C /\ A = B ) )
4	1 3	bitr4di	\|- ( ( C =/= (/) /\ A =/= (/) ) -> ( ( C X. A ) = ( C X. B ) <-> A = B ) )
5		nne	\|- ( -. A =/= (/) <-> A = (/) )
6		simpr	\|- ( ( C =/= (/) /\ A = (/) ) -> A = (/) )
7		xpeq2	\|- ( A = (/) -> ( C X. A ) = ( C X. (/) ) )
8		xp0	\|- ( C X. (/) ) = (/)
9	7 8	eqtrdi	\|- ( A = (/) -> ( C X. A ) = (/) )
10	9	eqeq1d	\|- ( A = (/) -> ( ( C X. A ) = ( C X. B ) <-> (/) = ( C X. B ) ) )
11		eqcom	\|- ( (/) = ( C X. B ) <-> ( C X. B ) = (/) )
12	10 11	bitrdi	\|- ( A = (/) -> ( ( C X. A ) = ( C X. B ) <-> ( C X. B ) = (/) ) )
13	12	adantl	\|- ( ( C =/= (/) /\ A = (/) ) -> ( ( C X. A ) = ( C X. B ) <-> ( C X. B ) = (/) ) )
14		df-ne	\|- ( C =/= (/) <-> -. C = (/) )
15		xpeq0	\|- ( ( C X. B ) = (/) <-> ( C = (/) \/ B = (/) ) )
16		orel1	\|- ( -. C = (/) -> ( ( C = (/) \/ B = (/) ) -> B = (/) ) )
17	15 16	biimtrid	\|- ( -. C = (/) -> ( ( C X. B ) = (/) -> B = (/) ) )
18	14 17	sylbi	\|- ( C =/= (/) -> ( ( C X. B ) = (/) -> B = (/) ) )
19	18	adantr	\|- ( ( C =/= (/) /\ A = (/) ) -> ( ( C X. B ) = (/) -> B = (/) ) )
20	13 19	sylbid	\|- ( ( C =/= (/) /\ A = (/) ) -> ( ( C X. A ) = ( C X. B ) -> B = (/) ) )
21		eqtr3	\|- ( ( A = (/) /\ B = (/) ) -> A = B )
22	6 20 21	syl6an	\|- ( ( C =/= (/) /\ A = (/) ) -> ( ( C X. A ) = ( C X. B ) -> A = B ) )
23	5 22	sylan2b	\|- ( ( C =/= (/) /\ -. A =/= (/) ) -> ( ( C X. A ) = ( C X. B ) -> A = B ) )
24		xpeq2	\|- ( A = B -> ( C X. A ) = ( C X. B ) )
25	23 24	impbid1	\|- ( ( C =/= (/) /\ -. A =/= (/) ) -> ( ( C X. A ) = ( C X. B ) <-> A = B ) )
26	4 25	pm2.61dan	\|- ( C =/= (/) -> ( ( C X. A ) = ( C X. B ) <-> A = B ) )

Metamath Proof Explorer

Theorem xpcan

Proof