csbin

Description: Distribute proper substitution into a class through an intersection relation. (Contributed by Alan Sare, 22-Jul-2012) (Revised by NM, 18-Aug-2018)

		Ref	Expression
	Assertion	csbin	\|- [_ A / x ]_ ( B i^i C ) = ( [_ A / x ]_ B i^i [_ A / x ]_ C )

Proof

Step	Hyp	Ref	Expression
1		csbeq1	\|- ( y = A -> [_ y / x ]_ ( B i^i C ) = [_ A / x ]_ ( B i^i C ) )
2		csbeq1	\|- ( y = A -> [_ y / x ]_ B = [_ A / x ]_ B )
3		csbeq1	\|- ( y = A -> [_ y / x ]_ C = [_ A / x ]_ C )
4	2 3	ineq12d	\|- ( y = A -> ( [_ y / x ]_ B i^i [_ y / x ]_ C ) = ( [_ A / x ]_ B i^i [_ A / x ]_ C ) )
5	1 4	eqeq12d	\|- ( y = A -> ( [_ y / x ]_ ( B i^i C ) = ( [_ y / x ]_ B i^i [_ y / x ]_ C ) <-> [_ A / x ]_ ( B i^i C ) = ( [_ A / x ]_ B i^i [_ A / x ]_ C ) ) )
6		vex	\|- y e. _V
7		nfcsb1v	\|- F/_ x [_ y / x ]_ B
8		nfcsb1v	\|- F/_ x [_ y / x ]_ C
9	7 8	nfin	\|- F/_ x ( [_ y / x ]_ B i^i [_ y / x ]_ C )
10		csbeq1a	\|- ( x = y -> B = [_ y / x ]_ B )
11		csbeq1a	\|- ( x = y -> C = [_ y / x ]_ C )
12	10 11	ineq12d	\|- ( x = y -> ( B i^i C ) = ( [_ y / x ]_ B i^i [_ y / x ]_ C ) )
13	6 9 12	csbief	\|- [_ y / x ]_ ( B i^i C ) = ( [_ y / x ]_ B i^i [_ y / x ]_ C )
14	5 13	vtoclg	\|- ( A e. _V -> [_ A / x ]_ ( B i^i C ) = ( [_ A / x ]_ B i^i [_ A / x ]_ C ) )
15		csbprc	\|- ( -. A e. _V -> [_ A / x ]_ ( B i^i C ) = (/) )
16		csbprc	\|- ( -. A e. _V -> [_ A / x ]_ B = (/) )
17		csbprc	\|- ( -. A e. _V -> [_ A / x ]_ C = (/) )
18	16 17	ineq12d	\|- ( -. A e. _V -> ( [_ A / x ]_ B i^i [_ A / x ]_ C ) = ( (/) i^i (/) ) )
19		in0	\|- ( (/) i^i (/) ) = (/)
20	18 19	eqtr2di	\|- ( -. A e. _V -> (/) = ( [_ A / x ]_ B i^i [_ A / x ]_ C ) )
21	15 20	eqtrd	\|- ( -. A e. _V -> [_ A / x ]_ ( B i^i C ) = ( [_ A / x ]_ B i^i [_ A / x ]_ C ) )
22	14 21	pm2.61i	\|- [_ A / x ]_ ( B i^i C ) = ( [_ A / x ]_ B i^i [_ A / x ]_ C )

Metamath Proof Explorer

Theorem csbin

Proof