satf0suc

Description: The value of the satisfaction predicate as function over wff codes in the empty model and the empty binary relation at a successor. (Contributed by AV, 19-Sep-2023)

		Ref	Expression
	Hypothesis	satf0suc.s	\|- S = ( (/) Sat (/) )
	Assertion	satf0suc	\|- ( N e. _om -> ( S ` suc N ) = ( ( S ` N ) u. { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) )

Proof

Step	Hyp	Ref	Expression
1		satf0suc.s	\|- S = ( (/) Sat (/) )
2	1	fveq1i	\|- ( S ` suc N ) = ( ( (/) Sat (/) ) ` suc N )
3	2	a1i	\|- ( N e. _om -> ( S ` suc N ) = ( ( (/) Sat (/) ) ` suc N ) )
4		omsucelsucb	\|- ( N e. _om <-> suc N e. suc _om )
5		satf0sucom	\|- ( suc N e. suc _om -> ( ( (/) Sat (/) ) ` suc N ) = ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` suc N ) )
6	4 5	sylbi	\|- ( N e. _om -> ( ( (/) Sat (/) ) ` suc N ) = ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` suc N ) )
7		nnon	\|- ( N e. _om -> N e. On )
8		rdgsuc	\|- ( N e. On -> ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` suc N ) = ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) ` ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` N ) ) )
9	7 8	syl	\|- ( N e. _om -> ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` suc N ) = ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) ` ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` N ) ) )
10	1	eqcomi	\|- ( (/) Sat (/) ) = S
11	10	fveq1i	\|- ( ( (/) Sat (/) ) ` N ) = ( S ` N )
12		elelsuc	\|- ( N e. _om -> N e. suc _om )
13		satf0sucom	\|- ( N e. suc _om -> ( ( (/) Sat (/) ) ` N ) = ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` N ) )
14	12 13	syl	\|- ( N e. _om -> ( ( (/) Sat (/) ) ` N ) = ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` N ) )
15	11 14	syl5reqr	\|- ( N e. _om -> ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` N ) = ( S ` N ) )
16	15	fveq2d	\|- ( N e. _om -> ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) ` ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` N ) ) = ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) ` ( S ` N ) ) )
17		eqidd	\|- ( N e. _om -> ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) = ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) )
18		id	\|- ( f = ( S ` N ) -> f = ( S ` N ) )
19		rexeq	\|- ( f = ( S ` N ) -> ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) <-> E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) ) )
20	19	orbi1d	\|- ( f = ( S ` N ) -> ( ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) <-> ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) )
21	20	rexeqbi1dv	\|- ( f = ( S ` N ) -> ( E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) <-> E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) )
22	21	anbi2d	\|- ( f = ( S ` N ) -> ( ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) <-> ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) ) )
23	22	opabbidv	\|- ( f = ( S ` N ) -> { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } = { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } )
24	18 23	uneq12d	\|- ( f = ( S ` N ) -> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) = ( ( S ` N ) u. { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) )
25	24	adantl	\|- ( ( N e. _om /\ f = ( S ` N ) ) -> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) = ( ( S ` N ) u. { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) )
26		fvex	\|- ( S ` N ) e. _V
27	26	a1i	\|- ( N e. _om -> ( S ` N ) e. _V )
28		omex	\|- _om e. _V
29		satf0suclem	\|- ( ( ( S ` N ) e. _V /\ ( S ` N ) e. _V /\ _om e. _V ) -> { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } e. _V )
30	26 26 28 29	mp3an	\|- { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } e. _V
31	26 30	unex	\|- ( ( S ` N ) u. { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) e. _V
32	31	a1i	\|- ( N e. _om -> ( ( S ` N ) u. { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) e. _V )
33	17 25 27 32	fvmptd	\|- ( N e. _om -> ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) ` ( S ` N ) ) = ( ( S ` N ) u. { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) )
34	9 16 33	3eqtrd	\|- ( N e. _om -> ( rec ( ( f e. _V \|-> ( f u. { <. x , y >. \| ( y = (/) /\ E. u e. f ( E. v e. f x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) ) , { <. x , y >. \| ( y = (/) /\ E. i e. _om E. j e. _om x = ( i e.g j ) ) } ) ` suc N ) = ( ( S ` N ) u. { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) )
35	3 6 34	3eqtrd	\|- ( N e. _om -> ( S ` suc N ) = ( ( S ` N ) u. { <. x , y >. \| ( y = (/) /\ E. u e. ( S ` N ) ( E. v e. ( S ` N ) x = ( ( 1st ` u ) \|g ( 1st ` v ) ) \/ E. i e. _om x = A.g i ( 1st ` u ) ) ) } ) )

Metamath Proof Explorer

Theorem satf0suc

Proof