unidifsnel

Description: The other element of a pair is an element of the pair. (Contributed by Thierry Arnoux, 26-Aug-2017)

		Ref	Expression
	Assertion	unidifsnel	\|- ( ( X e. P /\ P ~~ 2o ) -> U. ( P \ { X } ) e. P )

Proof

Step	Hyp	Ref	Expression
1		2onn	\|- 2o e. _om
2		nnfi	\|- ( 2o e. _om -> 2o e. Fin )
3	1 2	ax-mp	\|- 2o e. Fin
4		enfi	\|- ( P ~~ 2o -> ( P e. Fin <-> 2o e. Fin ) )
5	3 4	mpbiri	\|- ( P ~~ 2o -> P e. Fin )
6	5	adantl	\|- ( ( X e. P /\ P ~~ 2o ) -> P e. Fin )
7		diffi	\|- ( P e. Fin -> ( P \ { X } ) e. Fin )
8	6 7	syl	\|- ( ( X e. P /\ P ~~ 2o ) -> ( P \ { X } ) e. Fin )
9	8	cardidd	\|- ( ( X e. P /\ P ~~ 2o ) -> ( card ` ( P \ { X } ) ) ~~ ( P \ { X } ) )
10	9	ensymd	\|- ( ( X e. P /\ P ~~ 2o ) -> ( P \ { X } ) ~~ ( card ` ( P \ { X } ) ) )
11		simpl	\|- ( ( X e. P /\ P ~~ 2o ) -> X e. P )
12		dif1card	\|- ( ( P e. Fin /\ X e. P ) -> ( card ` P ) = suc ( card ` ( P \ { X } ) ) )
13	6 11 12	syl2anc	\|- ( ( X e. P /\ P ~~ 2o ) -> ( card ` P ) = suc ( card ` ( P \ { X } ) ) )
14		cardennn	\|- ( ( P ~~ 2o /\ 2o e. _om ) -> ( card ` P ) = 2o )
15	1 14	mpan2	\|- ( P ~~ 2o -> ( card ` P ) = 2o )
16		df-2o	\|- 2o = suc 1o
17	15 16	eqtrdi	\|- ( P ~~ 2o -> ( card ` P ) = suc 1o )
18	17	adantl	\|- ( ( X e. P /\ P ~~ 2o ) -> ( card ` P ) = suc 1o )
19	13 18	eqtr3d	\|- ( ( X e. P /\ P ~~ 2o ) -> suc ( card ` ( P \ { X } ) ) = suc 1o )
20		suc11reg	\|- ( suc ( card ` ( P \ { X } ) ) = suc 1o <-> ( card ` ( P \ { X } ) ) = 1o )
21	19 20	sylib	\|- ( ( X e. P /\ P ~~ 2o ) -> ( card ` ( P \ { X } ) ) = 1o )
22	10 21	breqtrd	\|- ( ( X e. P /\ P ~~ 2o ) -> ( P \ { X } ) ~~ 1o )
23		en1	\|- ( ( P \ { X } ) ~~ 1o <-> E. x ( P \ { X } ) = { x } )
24	22 23	sylib	\|- ( ( X e. P /\ P ~~ 2o ) -> E. x ( P \ { X } ) = { x } )
25		simpr	\|- ( ( ( X e. P /\ P ~~ 2o ) /\ ( P \ { X } ) = { x } ) -> ( P \ { X } ) = { x } )
26	25	unieqd	\|- ( ( ( X e. P /\ P ~~ 2o ) /\ ( P \ { X } ) = { x } ) -> U. ( P \ { X } ) = U. { x } )
27		unisnv	\|- U. { x } = x
28	26 27	eqtrdi	\|- ( ( ( X e. P /\ P ~~ 2o ) /\ ( P \ { X } ) = { x } ) -> U. ( P \ { X } ) = x )
29		difssd	\|- ( ( ( X e. P /\ P ~~ 2o ) /\ ( P \ { X } ) = { x } ) -> ( P \ { X } ) C_ P )
30	25 29	eqsstrrd	\|- ( ( ( X e. P /\ P ~~ 2o ) /\ ( P \ { X } ) = { x } ) -> { x } C_ P )
31		vsnid	\|- x e. { x }
32		ssel2	\|- ( ( { x } C_ P /\ x e. { x } ) -> x e. P )
33	30 31 32	sylancl	\|- ( ( ( X e. P /\ P ~~ 2o ) /\ ( P \ { X } ) = { x } ) -> x e. P )
34	28 33	eqeltrd	\|- ( ( ( X e. P /\ P ~~ 2o ) /\ ( P \ { X } ) = { x } ) -> U. ( P \ { X } ) e. P )
35	24 34	exlimddv	\|- ( ( X e. P /\ P ~~ 2o ) -> U. ( P \ { X } ) e. P )

Metamath Proof Explorer

Theorem unidifsnel

Proof