df-fuc

Description: Definition of the category of functors between two fixed categories, with the objects being functors and the morphisms being natural transformations. Definition 6.15 in Adamek p. 87. (Contributed by Mario Carneiro, 6-Jan-2017)

		Ref	Expression
	Assertion	df-fuc	\|- FuncCat = ( t e. Cat , u e. Cat \|-> { <. ( Base ` ndx ) , ( t Func u ) >. , <. ( Hom ` ndx ) , ( t Nat u ) >. , <. ( comp ` ndx ) , ( v e. ( ( t Func u ) X. ( t Func u ) ) , h e. ( t Func u ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( t Nat u ) h ) , a e. ( f ( t Nat u ) g ) \|-> ( x e. ( Base ` t ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) >. } )

Detailed syntax breakdown

Step	Hyp	Ref	Expression
0		cfuc	\|- FuncCat
1		vt	\|- t
2		ccat	\|- Cat
3		vu	\|- u
4		cbs	\|- Base
5		cnx	\|- ndx
6	5 4	cfv	\|- ( Base ` ndx )
7	1	cv	\|- t
8		cfunc	\|- Func
9	3	cv	\|- u
10	7 9 8	co	\|- ( t Func u )
11	6 10	cop	\|- <. ( Base ` ndx ) , ( t Func u ) >.
12		chom	\|- Hom
13	5 12	cfv	\|- ( Hom ` ndx )
14		cnat	\|- Nat
15	7 9 14	co	\|- ( t Nat u )
16	13 15	cop	\|- <. ( Hom ` ndx ) , ( t Nat u ) >.
17		cco	\|- comp
18	5 17	cfv	\|- ( comp ` ndx )
19		vv	\|- v
20	10 10	cxp	\|- ( ( t Func u ) X. ( t Func u ) )
21		vh	\|- h
22		c1st	\|- 1st
23	19	cv	\|- v
24	23 22	cfv	\|- ( 1st ` v )
25		vf	\|- f
26		c2nd	\|- 2nd
27	23 26	cfv	\|- ( 2nd ` v )
28		vg	\|- g
29		vb	\|- b
30	28	cv	\|- g
31	21	cv	\|- h
32	30 31 15	co	\|- ( g ( t Nat u ) h )
33		va	\|- a
34	25	cv	\|- f
35	34 30 15	co	\|- ( f ( t Nat u ) g )
36		vx	\|- x
37	7 4	cfv	\|- ( Base ` t )
38	29	cv	\|- b
39	36	cv	\|- x
40	39 38	cfv	\|- ( b ` x )
41	34 22	cfv	\|- ( 1st ` f )
42	39 41	cfv	\|- ( ( 1st ` f ) ` x )
43	30 22	cfv	\|- ( 1st ` g )
44	39 43	cfv	\|- ( ( 1st ` g ) ` x )
45	42 44	cop	\|- <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >.
46	9 17	cfv	\|- ( comp ` u )
47	31 22	cfv	\|- ( 1st ` h )
48	39 47	cfv	\|- ( ( 1st ` h ) ` x )
49	45 48 46	co	\|- ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) )
50	33	cv	\|- a
51	39 50	cfv	\|- ( a ` x )
52	40 51 49	co	\|- ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) )
53	36 37 52	cmpt	\|- ( x e. ( Base ` t ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) )
54	29 33 32 35 53	cmpo	\|- ( b e. ( g ( t Nat u ) h ) , a e. ( f ( t Nat u ) g ) \|-> ( x e. ( Base ` t ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) )
55	28 27 54	csb	\|- [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( t Nat u ) h ) , a e. ( f ( t Nat u ) g ) \|-> ( x e. ( Base ` t ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) )
56	25 24 55	csb	\|- [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( t Nat u ) h ) , a e. ( f ( t Nat u ) g ) \|-> ( x e. ( Base ` t ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) )
57	19 21 20 10 56	cmpo	\|- ( v e. ( ( t Func u ) X. ( t Func u ) ) , h e. ( t Func u ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( t Nat u ) h ) , a e. ( f ( t Nat u ) g ) \|-> ( x e. ( Base ` t ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) )
58	18 57	cop	\|- <. ( comp ` ndx ) , ( v e. ( ( t Func u ) X. ( t Func u ) ) , h e. ( t Func u ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( t Nat u ) h ) , a e. ( f ( t Nat u ) g ) \|-> ( x e. ( Base ` t ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) >.
59	11 16 58	ctp	\|- { <. ( Base ` ndx ) , ( t Func u ) >. , <. ( Hom ` ndx ) , ( t Nat u ) >. , <. ( comp ` ndx ) , ( v e. ( ( t Func u ) X. ( t Func u ) ) , h e. ( t Func u ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( t Nat u ) h ) , a e. ( f ( t Nat u ) g ) \|-> ( x e. ( Base ` t ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) >. }
60	1 3 2 2 59	cmpo	\|- ( t e. Cat , u e. Cat \|-> { <. ( Base ` ndx ) , ( t Func u ) >. , <. ( Hom ` ndx ) , ( t Nat u ) >. , <. ( comp ` ndx ) , ( v e. ( ( t Func u ) X. ( t Func u ) ) , h e. ( t Func u ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( t Nat u ) h ) , a e. ( f ( t Nat u ) g ) \|-> ( x e. ( Base ` t ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) >. } )
61	0 60	wceq	\|- FuncCat = ( t e. Cat , u e. Cat \|-> { <. ( Base ` ndx ) , ( t Func u ) >. , <. ( Hom ` ndx ) , ( t Nat u ) >. , <. ( comp ` ndx ) , ( v e. ( ( t Func u ) X. ( t Func u ) ) , h e. ( t Func u ) \|-> [_ ( 1st ` v ) / f ]_ [_ ( 2nd ` v ) / g ]_ ( b e. ( g ( t Nat u ) h ) , a e. ( f ( t Nat u ) g ) \|-> ( x e. ( Base ` t ) \|-> ( ( b ` x ) ( <. ( ( 1st ` f ) ` x ) , ( ( 1st ` g ) ` x ) >. ( comp ` u ) ( ( 1st ` h ) ` x ) ) ( a ` x ) ) ) ) ) >. } )

Metamath Proof Explorer

Definition df-fuc

Detailed syntax breakdown