dif1ennnALT

Description: Alternate proof of dif1ennn using ax-pow . (Contributed by Jeff Madsen, 2-Sep-2009) (Revised by Stefan O'Rear, 16-Aug-2015) (Proof modification is discouraged.) (New usage is discouraged.)

		Ref	Expression
	Assertion	dif1ennnALT	\|- ( ( M e. _om /\ A ~~ suc M /\ X e. A ) -> ( A \ { X } ) ~~ M )

Proof

Step	Hyp	Ref	Expression
1		peano2	\|- ( M e. _om -> suc M e. _om )
2		breq2	\|- ( x = suc M -> ( A ~~ x <-> A ~~ suc M ) )
3	2	rspcev	\|- ( ( suc M e. _om /\ A ~~ suc M ) -> E. x e. _om A ~~ x )
4		isfi	\|- ( A e. Fin <-> E. x e. _om A ~~ x )
5	3 4	sylibr	\|- ( ( suc M e. _om /\ A ~~ suc M ) -> A e. Fin )
6	1 5	sylan	\|- ( ( M e. _om /\ A ~~ suc M ) -> A e. Fin )
7		diffi	\|- ( A e. Fin -> ( A \ { X } ) e. Fin )
8		isfi	\|- ( ( A \ { X } ) e. Fin <-> E. x e. _om ( A \ { X } ) ~~ x )
9	7 8	sylib	\|- ( A e. Fin -> E. x e. _om ( A \ { X } ) ~~ x )
10	6 9	syl	\|- ( ( M e. _om /\ A ~~ suc M ) -> E. x e. _om ( A \ { X } ) ~~ x )
11	10	3adant3	\|- ( ( M e. _om /\ A ~~ suc M /\ X e. A ) -> E. x e. _om ( A \ { X } ) ~~ x )
12		en2sn	\|- ( ( X e. A /\ x e. _V ) -> { X } ~~ { x } )
13	12	elvd	\|- ( X e. A -> { X } ~~ { x } )
14		nnord	\|- ( x e. _om -> Ord x )
15		orddisj	\|- ( Ord x -> ( x i^i { x } ) = (/) )
16	14 15	syl	\|- ( x e. _om -> ( x i^i { x } ) = (/) )
17		incom	\|- ( ( A \ { X } ) i^i { X } ) = ( { X } i^i ( A \ { X } ) )
18		disjdif	\|- ( { X } i^i ( A \ { X } ) ) = (/)
19	17 18	eqtri	\|- ( ( A \ { X } ) i^i { X } ) = (/)
20		unen	\|- ( ( ( ( A \ { X } ) ~~ x /\ { X } ~~ { x } ) /\ ( ( ( A \ { X } ) i^i { X } ) = (/) /\ ( x i^i { x } ) = (/) ) ) -> ( ( A \ { X } ) u. { X } ) ~~ ( x u. { x } ) )
21	20	an4s	\|- ( ( ( ( A \ { X } ) ~~ x /\ ( ( A \ { X } ) i^i { X } ) = (/) ) /\ ( { X } ~~ { x } /\ ( x i^i { x } ) = (/) ) ) -> ( ( A \ { X } ) u. { X } ) ~~ ( x u. { x } ) )
22	19 21	mpanl2	\|- ( ( ( A \ { X } ) ~~ x /\ ( { X } ~~ { x } /\ ( x i^i { x } ) = (/) ) ) -> ( ( A \ { X } ) u. { X } ) ~~ ( x u. { x } ) )
23	22	expcom	\|- ( ( { X } ~~ { x } /\ ( x i^i { x } ) = (/) ) -> ( ( A \ { X } ) ~~ x -> ( ( A \ { X } ) u. { X } ) ~~ ( x u. { x } ) ) )
24	13 16 23	syl2an	\|- ( ( X e. A /\ x e. _om ) -> ( ( A \ { X } ) ~~ x -> ( ( A \ { X } ) u. { X } ) ~~ ( x u. { x } ) ) )
25	24	3ad2antl3	\|- ( ( ( M e. _om /\ A ~~ suc M /\ X e. A ) /\ x e. _om ) -> ( ( A \ { X } ) ~~ x -> ( ( A \ { X } ) u. { X } ) ~~ ( x u. { x } ) ) )
26		difsnid	\|- ( X e. A -> ( ( A \ { X } ) u. { X } ) = A )
27		df-suc	\|- suc x = ( x u. { x } )
28	27	eqcomi	\|- ( x u. { x } ) = suc x
29	28	a1i	\|- ( X e. A -> ( x u. { x } ) = suc x )
30	26 29	breq12d	\|- ( X e. A -> ( ( ( A \ { X } ) u. { X } ) ~~ ( x u. { x } ) <-> A ~~ suc x ) )
31	30	3ad2ant3	\|- ( ( M e. _om /\ A ~~ suc M /\ X e. A ) -> ( ( ( A \ { X } ) u. { X } ) ~~ ( x u. { x } ) <-> A ~~ suc x ) )
32	31	adantr	\|- ( ( ( M e. _om /\ A ~~ suc M /\ X e. A ) /\ x e. _om ) -> ( ( ( A \ { X } ) u. { X } ) ~~ ( x u. { x } ) <-> A ~~ suc x ) )
33		ensym	\|- ( A ~~ suc M -> suc M ~~ A )
34		entr	\|- ( ( suc M ~~ A /\ A ~~ suc x ) -> suc M ~~ suc x )
35		peano2	\|- ( x e. _om -> suc x e. _om )
36		nneneq	\|- ( ( suc M e. _om /\ suc x e. _om ) -> ( suc M ~~ suc x <-> suc M = suc x ) )
37	35 36	sylan2	\|- ( ( suc M e. _om /\ x e. _om ) -> ( suc M ~~ suc x <-> suc M = suc x ) )
38	34 37	imbitrid	\|- ( ( suc M e. _om /\ x e. _om ) -> ( ( suc M ~~ A /\ A ~~ suc x ) -> suc M = suc x ) )
39	38	expd	\|- ( ( suc M e. _om /\ x e. _om ) -> ( suc M ~~ A -> ( A ~~ suc x -> suc M = suc x ) ) )
40	33 39	syl5	\|- ( ( suc M e. _om /\ x e. _om ) -> ( A ~~ suc M -> ( A ~~ suc x -> suc M = suc x ) ) )
41	1 40	sylan	\|- ( ( M e. _om /\ x e. _om ) -> ( A ~~ suc M -> ( A ~~ suc x -> suc M = suc x ) ) )
42	41	imp	\|- ( ( ( M e. _om /\ x e. _om ) /\ A ~~ suc M ) -> ( A ~~ suc x -> suc M = suc x ) )
43	42	an32s	\|- ( ( ( M e. _om /\ A ~~ suc M ) /\ x e. _om ) -> ( A ~~ suc x -> suc M = suc x ) )
44	43	3adantl3	\|- ( ( ( M e. _om /\ A ~~ suc M /\ X e. A ) /\ x e. _om ) -> ( A ~~ suc x -> suc M = suc x ) )
45	32 44	sylbid	\|- ( ( ( M e. _om /\ A ~~ suc M /\ X e. A ) /\ x e. _om ) -> ( ( ( A \ { X } ) u. { X } ) ~~ ( x u. { x } ) -> suc M = suc x ) )
46		peano4	\|- ( ( M e. _om /\ x e. _om ) -> ( suc M = suc x <-> M = x ) )
47	46	biimpd	\|- ( ( M e. _om /\ x e. _om ) -> ( suc M = suc x -> M = x ) )
48	47	3ad2antl1	\|- ( ( ( M e. _om /\ A ~~ suc M /\ X e. A ) /\ x e. _om ) -> ( suc M = suc x -> M = x ) )
49	25 45 48	3syld	\|- ( ( ( M e. _om /\ A ~~ suc M /\ X e. A ) /\ x e. _om ) -> ( ( A \ { X } ) ~~ x -> M = x ) )
50		breq2	\|- ( M = x -> ( ( A \ { X } ) ~~ M <-> ( A \ { X } ) ~~ x ) )
51	50	biimprcd	\|- ( ( A \ { X } ) ~~ x -> ( M = x -> ( A \ { X } ) ~~ M ) )
52	49 51	sylcom	\|- ( ( ( M e. _om /\ A ~~ suc M /\ X e. A ) /\ x e. _om ) -> ( ( A \ { X } ) ~~ x -> ( A \ { X } ) ~~ M ) )
53	52	rexlimdva	\|- ( ( M e. _om /\ A ~~ suc M /\ X e. A ) -> ( E. x e. _om ( A \ { X } ) ~~ x -> ( A \ { X } ) ~~ M ) )
54	11 53	mpd	\|- ( ( M e. _om /\ A ~~ suc M /\ X e. A ) -> ( A \ { X } ) ~~ M )

Metamath Proof Explorer

Theorem dif1ennnALT

Proof