onfrALTVD

Description: Virtual deduction proof of onfrALT . The following User's Proof is a Virtual Deduction proof completed automatically by the tools program completeusersproof.cmd, which invokes Mel L. O'Cat's mmj2 and Norm Megill's Metamath Proof Assistant. onfrALT is onfrALTVD without virtual deductions and was automatically derived from onfrALTVD .

		Ref	Expression
	Assertion	onfrALTVD	\|- _E Fr On

Proof

Step	Hyp	Ref	Expression
1		idn1	\|- (. ( a C_ On /\ a =/= (/) ) ->. ( a C_ On /\ a =/= (/) ) ).
2		simpr	\|- ( ( a C_ On /\ a =/= (/) ) -> a =/= (/) )
3	1 2	e1a	\|- (. ( a C_ On /\ a =/= (/) ) ->. a =/= (/) ).
4		exmid	\|- ( ( a i^i x ) = (/) \/ -. ( a i^i x ) = (/) )
5		onfrALTlem1VD	\|- (. ( a C_ On /\ a =/= (/) ) ,. ( x e. a /\ ( a i^i x ) = (/) ) ->. E. y e. a ( a i^i y ) = (/) ).
6	5	in2an	\|- (. ( a C_ On /\ a =/= (/) ) ,. x e. a ->. ( ( a i^i x ) = (/) -> E. y e. a ( a i^i y ) = (/) ) ).
7		onfrALTlem2VD	\|- (. ( a C_ On /\ a =/= (/) ) ,. ( x e. a /\ -. ( a i^i x ) = (/) ) ->. E. y e. a ( a i^i y ) = (/) ).
8	7	in2an	\|- (. ( a C_ On /\ a =/= (/) ) ,. x e. a ->. ( -. ( a i^i x ) = (/) -> E. y e. a ( a i^i y ) = (/) ) ).
9		pm2.61	\|- ( ( ( a i^i x ) = (/) -> E. y e. a ( a i^i y ) = (/) ) -> ( ( -. ( a i^i x ) = (/) -> E. y e. a ( a i^i y ) = (/) ) -> E. y e. a ( a i^i y ) = (/) ) )
10	9	a1i	\|- ( ( ( a i^i x ) = (/) \/ -. ( a i^i x ) = (/) ) -> ( ( ( a i^i x ) = (/) -> E. y e. a ( a i^i y ) = (/) ) -> ( ( -. ( a i^i x ) = (/) -> E. y e. a ( a i^i y ) = (/) ) -> E. y e. a ( a i^i y ) = (/) ) ) )
11	4 6 8 10	e022	\|- (. ( a C_ On /\ a =/= (/) ) ,. x e. a ->. E. y e. a ( a i^i y ) = (/) ).
12	11	in2	\|- (. ( a C_ On /\ a =/= (/) ) ->. ( x e. a -> E. y e. a ( a i^i y ) = (/) ) ).
13	12	gen11	\|- (. ( a C_ On /\ a =/= (/) ) ->. A. x ( x e. a -> E. y e. a ( a i^i y ) = (/) ) ).
14		19.23v	\|- ( A. x ( x e. a -> E. y e. a ( a i^i y ) = (/) ) <-> ( E. x x e. a -> E. y e. a ( a i^i y ) = (/) ) )
15	14	biimpi	\|- ( A. x ( x e. a -> E. y e. a ( a i^i y ) = (/) ) -> ( E. x x e. a -> E. y e. a ( a i^i y ) = (/) ) )
16	13 15	e1a	\|- (. ( a C_ On /\ a =/= (/) ) ->. ( E. x x e. a -> E. y e. a ( a i^i y ) = (/) ) ).
17		n0	\|- ( a =/= (/) <-> E. x x e. a )
18		imbi1	\|- ( ( a =/= (/) <-> E. x x e. a ) -> ( ( a =/= (/) -> E. y e. a ( a i^i y ) = (/) ) <-> ( E. x x e. a -> E. y e. a ( a i^i y ) = (/) ) ) )
19	18	biimprcd	\|- ( ( E. x x e. a -> E. y e. a ( a i^i y ) = (/) ) -> ( ( a =/= (/) <-> E. x x e. a ) -> ( a =/= (/) -> E. y e. a ( a i^i y ) = (/) ) ) )
20	16 17 19	e10	\|- (. ( a C_ On /\ a =/= (/) ) ->. ( a =/= (/) -> E. y e. a ( a i^i y ) = (/) ) ).
21		pm2.27	\|- ( a =/= (/) -> ( ( a =/= (/) -> E. y e. a ( a i^i y ) = (/) ) -> E. y e. a ( a i^i y ) = (/) ) )
22	3 20 21	e11	\|- (. ( a C_ On /\ a =/= (/) ) ->. E. y e. a ( a i^i y ) = (/) ).
23	22	in1	\|- ( ( a C_ On /\ a =/= (/) ) -> E. y e. a ( a i^i y ) = (/) )
24	23	ax-gen	\|- A. a ( ( a C_ On /\ a =/= (/) ) -> E. y e. a ( a i^i y ) = (/) )
25		dfepfr	\|- ( _E Fr On <-> A. a ( ( a C_ On /\ a =/= (/) ) -> E. y e. a ( a i^i y ) = (/) ) )
26	25	biimpri	\|- ( A. a ( ( a C_ On /\ a =/= (/) ) -> E. y e. a ( a i^i y ) = (/) ) -> _E Fr On )
27	24 26	e0a	\|- _E Fr On

Metamath Proof Explorer

Theorem onfrALTVD

Proof

1::	\|- (. ( a C_ On /\ a =/= (/) ) ,. ( x e. a /\ -. ( a i^i x ) = (/) ) ->. E. y e. a ( a i^i y ) = (/) ).
2::	\|- (. ( a C_ On /\ a =/= (/) ) ,. ( x e. a /\ ( a i^i x ) = (/) ) ->. E. y e. a ( a i^i y ) = (/) ).
3:1:	\|- (. ( a C_ On /\ a =/= (/) ) ,. x e. a ->. ( -. ( a i^i x ) = (/) -> E. y e. a ( a i^i y ) = (/) ) ).
4:2:	\|- (. ( a C_ On /\ a =/= (/) ) ,. x e. a ->. ( ( a i^i x ) = (/) -> E. y e. a ( a i^i y ) = (/) ) ).
5::	\|- ( ( a i^i x ) = (/) \/ -. ( a i^i x ) = (/) )
6:5,4,3:	\|- (. ( a C_ On /\ a =/= (/) ) ,. x e. a ->. E. y e. a ( a i^i y ) = (/) ).
7:6:	\|- (. ( a C_ On /\ a =/= (/) ) ->. ( x e. a -> E. y e. a ( a i^i y ) = (/) ) ).
8:7:	\|- (. ( a C_ On /\ a =/= (/) ) ->. A. x ( x e. a -> E. y e. a ( a i^i y ) = (/) ) ).
9:8:	\|- (. ( a C_ On /\ a =/= (/) ) ->. ( E. x x e. a -> E. y e. a ( a i^i y ) = (/) ) ).
10::	\|- ( a =/= (/) <-> E. x x e. a )
11:9,10:	\|- (. ( a C_ On /\ a =/= (/) ) ->. ( a =/= (/) -> E. y e. a ( a i^i y ) = (/) ) ).
12::	\|- (. ( a C_ On /\ a =/= (/) ) ->. ( a C_ On /\ a =/= (/) ) ).
13:12:	\|- (. ( a C_ On /\ a =/= (/) ) ->. a =/= (/) ).
14:13,11:	\|- (. ( a C_ On /\ a =/= (/) ) ->. E. y e. a ( a i^i y ) = (/) ).
15:14:	\|- ( ( a C_ On /\ a =/= (/) ) -> E. y e. a ( a i^i y ) = (/) )
16:15:	\|- A. a ( ( a C_ On /\ a =/= (/) ) -> E. y e. a ( a i^i y ) = (/) )
qed:16:	\|- _E Fr On