catcfucclOLD

Description: Obsolete proof of catcfuccl as of 14-Oct-2024. (Contributed by Mario Carneiro, 12-Jan-2017) (Proof modification is discouraged.) (New usage is discouraged.)

	Ref	Expression
Hypotheses	catcfuccl.c	\|- C = ( CatCat ` U )
	catcfuccl.b	\|- B = ( Base ` C )
	catcfuccl.o	\|- Q = ( X FuncCat Y )
	catcfuccl.u	\|- ( ph -> U e. WUni )
	catcfuccl.1	\|- ( ph -> _om e. U )
	catcfuccl.x	\|- ( ph -> X e. B )
	catcfuccl.y	\|- ( ph -> Y e. B )
Assertion	catcfucclOLD	\|- ( ph -> Q e. B )

Proof

Step	Hyp	Ref	Expression
1		catcfuccl.c	\|- C = ( CatCat ` U )
2		catcfuccl.b	\|- B = ( Base ` C )
3		catcfuccl.o	\|- Q = ( X FuncCat Y )
4		catcfuccl.u	\|- ( ph -> U e. WUni )
5		catcfuccl.1	\|- ( ph -> _om e. U )
6		catcfuccl.x	\|- ( ph -> X e. B )
7		catcfuccl.y	\|- ( ph -> Y e. B )
8		eqid	\|- ( X Func Y ) = ( X Func Y )
9		eqid	\|- ( X Nat Y ) = ( X Nat Y )
10		eqid	\|- ( Base ` X ) = ( Base ` X )
11		eqid	\|- ( comp ` Y ) = ( comp ` Y )
12	1 2 4	catcbas	\|- ( ph -> B = ( U i^i Cat ) )
13	6 12	eleqtrd	\|- ( ph -> X e. ( U i^i Cat ) )
14	13	elin2d	\|- ( ph -> X e. Cat )
15	7 12	eleqtrd	\|- ( ph -> Y e. ( U i^i Cat ) )
16	15	elin2d	\|- ( ph -> Y e. Cat )
17		eqidd	\|- ( ph -> ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) = ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) )
18	3 8 9 10 11 14 16 17	fucval	\|- ( ph -> Q = { <. ( Base ` ndx ) , ( X Func Y ) >. , <. ( Hom ` ndx ) , ( X Nat Y ) >. , <. ( comp ` ndx ) , ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) >. } )
19		df-base	\|- Base = Slot 1
20	4 5	wunndx	\|- ( ph -> ndx e. U )
21	19 4 20	wunstr	\|- ( ph -> ( Base ` ndx ) e. U )
22	13	elin1d	\|- ( ph -> X e. U )
23	15	elin1d	\|- ( ph -> Y e. U )
24	4 22 23	wunfunc	\|- ( ph -> ( X Func Y ) e. U )
25	4 21 24	wunop	\|- ( ph -> <. ( Base ` ndx ) , ( X Func Y ) >. e. U )
26		df-hom	\|- Hom = Slot ; 1 4
27	26 4 20	wunstr	\|- ( ph -> ( Hom ` ndx ) e. U )
28	4 22 23	wunnat	\|- ( ph -> ( X Nat Y ) e. U )
29	4 27 28	wunop	\|- ( ph -> <. ( Hom ` ndx ) , ( X Nat Y ) >. e. U )
30		df-cco	\|- comp = Slot ; 1 5
31	30 4 20	wunstr	\|- ( ph -> ( comp ` ndx ) e. U )
32	4 24 24	wunxp	\|- ( ph -> ( ( X Func Y ) X. ( X Func Y ) ) e. U )
33	4 32 24	wunxp	\|- ( ph -> ( ( ( X Func Y ) X. ( X Func Y ) ) X. ( X Func Y ) ) e. U )
34	30 4 23	wunstr	\|- ( ph -> ( comp ` Y ) e. U )
35	4 34	wunrn	\|- ( ph -> ran ( comp ` Y ) e. U )
36	4 35	wununi	\|- ( ph -> U. ran ( comp ` Y ) e. U )
37	4 36	wunrn	\|- ( ph -> ran U. ran ( comp ` Y ) e. U )
38	4 37	wununi	\|- ( ph -> U. ran U. ran ( comp ` Y ) e. U )
39	4 38	wunpw	\|- ( ph -> ~P U. ran U. ran ( comp ` Y ) e. U )
40	19 4 22	wunstr	\|- ( ph -> ( Base ` X ) e. U )
41	4 39 40	wunmap	\|- ( ph -> ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) e. U )
42	4 28	wunrn	\|- ( ph -> ran ( X Nat Y ) e. U )
43	4 42	wununi	\|- ( ph -> U. ran ( X Nat Y ) e. U )
44	4 43 43	wunxp	\|- ( ph -> ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) e. U )
45	4 41 44	wunpm	\|- ( ph -> ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) e. U )
46		fvex	\|- ( 1st ` v ) e. _V
47		fvex	\|- ( 2nd ` v ) e. _V
48		ovex	\|- ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) e. _V
49		ovex	\|- ( X Nat Y ) e. _V
50	49	rnex	\|- ran ( X Nat Y ) e. _V
51	50	uniex	\|- U. ran ( X Nat Y ) e. _V
52	51 51	xpex	\|- ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) e. _V
53		eqid	\|- ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) = ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) )
54		ovssunirn	\|- ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) C_ U. ran ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) )
55		ovssunirn	\|- ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) C_ U. ran ( comp ` Y )
56		rnss	\|- ( ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) C_ U. ran ( comp ` Y ) -> ran ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) C_ ran U. ran ( comp ` Y ) )
57		uniss	\|- ( ran ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) C_ ran U. ran ( comp ` Y ) -> U. ran ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) C_ U. ran U. ran ( comp ` Y ) )
58	55 56 57	mp2b	\|- U. ran ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) C_ U. ran U. ran ( comp ` Y )
59	54 58	sstri	\|- ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) C_ U. ran U. ran ( comp ` Y )
60		ovex	\|- ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) e. _V
61	60	elpw	\|- ( ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) e. ~P U. ran U. ran ( comp ` Y ) <-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) C_ U. ran U. ran ( comp ` Y ) )
62	59 61	mpbir	\|- ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) e. ~P U. ran U. ran ( comp ` Y )
63	62	a1i	\|- ( x e. ( Base ` X ) -> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) e. ~P U. ran U. ran ( comp ` Y ) )
64	53 63	fmpti	\|- ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) : ( Base ` X ) --> ~P U. ran U. ran ( comp ` Y )
65		fvex	\|- ( comp ` Y ) e. _V
66	65	rnex	\|- ran ( comp ` Y ) e. _V
67	66	uniex	\|- U. ran ( comp ` Y ) e. _V
68	67	rnex	\|- ran U. ran ( comp ` Y ) e. _V
69	68	uniex	\|- U. ran U. ran ( comp ` Y ) e. _V
70	69	pwex	\|- ~P U. ran U. ran ( comp ` Y ) e. _V
71		fvex	\|- ( Base ` X ) e. _V
72	70 71	elmap	\|- ( ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) e. ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) <-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) : ( Base ` X ) --> ~P U. ran U. ran ( comp ` Y ) )
73	64 72	mpbir	\|- ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) e. ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) )
74	73	rgen2w	\|- A. b e. ( g ( X Nat Y ) h ) A. a e. ( f ( X Nat Y ) g ) ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) e. ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) )
75		eqid	\|- ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) = ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) )
76	75	fmpo	\|- ( A. b e. ( g ( X Nat Y ) h ) A. a e. ( f ( X Nat Y ) g ) ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) e. ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) <-> ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) : ( ( g ( X Nat Y ) h ) X. ( f ( X Nat Y ) g ) ) --> ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) )
77	74 76	mpbi	\|- ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) : ( ( g ( X Nat Y ) h ) X. ( f ( X Nat Y ) g ) ) --> ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) )
78		ovssunirn	\|- ( g ( X Nat Y ) h ) C_ U. ran ( X Nat Y )
79		ovssunirn	\|- ( f ( X Nat Y ) g ) C_ U. ran ( X Nat Y )
80		xpss12	\|- ( ( ( g ( X Nat Y ) h ) C_ U. ran ( X Nat Y ) /\ ( f ( X Nat Y ) g ) C_ U. ran ( X Nat Y ) ) -> ( ( g ( X Nat Y ) h ) X. ( f ( X Nat Y ) g ) ) C_ ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) )
81	78 79 80	mp2an	\|- ( ( g ( X Nat Y ) h ) X. ( f ( X Nat Y ) g ) ) C_ ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) )
82		elpm2r	\|- ( ( ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) e. _V /\ ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) e. _V ) /\ ( ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) : ( ( g ( X Nat Y ) h ) X. ( f ( X Nat Y ) g ) ) --> ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) /\ ( ( g ( X Nat Y ) h ) X. ( f ( X Nat Y ) g ) ) C_ ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) ) -> ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) )
83	48 52 77 81 82	mp4an	\|- ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) )
84	83	sbcth	\|- ( ( 2nd ` v ) e. _V -> [. ( 2nd ` v ) / g ]. ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) )
85		sbcel1g	\|- ( ( 2nd ` v ) e. _V -> ( [. ( 2nd ` v ) / g ]. ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) <-> [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) ) )
86	84 85	mpbid	\|- ( ( 2nd ` v ) e. _V -> [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) )
87	47 86	ax-mp	\|- [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) )
88	87	sbcth	\|- ( ( 1st ` v ) e. _V -> [. ( 1st ` v ) / f ]. [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) )
89		sbcel1g	\|- ( ( 1st ` v ) e. _V -> ( [. ( 1st ` v ) / f ]. [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) <-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) ) )
90	88 89	mpbid	\|- ( ( 1st ` v ) e. _V -> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) )
91	46 90	ax-mp	\|- [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) )
92	91	rgen2w	\|- A. v e. ( ( X Func Y ) X. ( X Func Y ) ) A. h e. ( X Func Y ) [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) )
93		eqid	\|- ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) = ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) )
94	93	fmpo	\|- ( A. v e. ( ( X Func Y ) X. ( X Func Y ) ) A. h e. ( X Func Y ) [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) e. ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) <-> ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) : ( ( ( X Func Y ) X. ( X Func Y ) ) X. ( X Func Y ) ) --> ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) )
95	92 94	mpbi	\|- ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) : ( ( ( X Func Y ) X. ( X Func Y ) ) X. ( X Func Y ) ) --> ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) )
96	95	a1i	\|- ( ph -> ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) : ( ( ( X Func Y ) X. ( X Func Y ) ) X. ( X Func Y ) ) --> ( ( ~P U. ran U. ran ( comp ` Y ) ^m ( Base ` X ) ) ^pm ( U. ran ( X Nat Y ) X. U. ran ( X Nat Y ) ) ) )
97	4 33 45 96	wunf	\|- ( ph -> ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) e. U )
98	4 31 97	wunop	\|- ( ph -> <. ( comp ` ndx ) , ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) >. e. U )
99	4 25 29 98	wuntp	\|- ( ph -> { <. ( Base ` ndx ) , ( X Func Y ) >. , <. ( Hom ` ndx ) , ( X Nat Y ) >. , <. ( comp ` ndx ) , ( v e. ( ( X Func Y ) X. ( X Func Y ) ) , h e. ( X Func Y ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( X Nat Y ) h ) , a e. ( f ( X Nat Y ) g ) \|-> ( x e. ( Base ` X ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` Y ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) >. } e. U )
100	18 99	eqeltrd	\|- ( ph -> Q e. U )
101	3 14 16	fuccat	\|- ( ph -> Q e. Cat )
102	100 101	elind	\|- ( ph -> Q e. ( U i^i Cat ) )
103	102 12	eleqtrrd	\|- ( ph -> Q e. B )

Metamath Proof Explorer

Theorem catcfucclOLD

Proof