subsubc

Description: A subcategory of a subcategory is a subcategory. (Contributed by Mario Carneiro, 6-Jan-2017)

		Ref	Expression
	Hypothesis	subsubc.d	\|- D = ( C \|`cat H )
	Assertion	subsubc	\|- ( H e. ( Subcat ` C ) -> ( J e. ( Subcat ` D ) <-> ( J e. ( Subcat ` C ) /\ J C_cat H ) ) )

Proof

Step	Hyp	Ref	Expression
1		subsubc.d	\|- D = ( C \|`cat H )
2		id	\|- ( J e. ( Subcat ` D ) -> J e. ( Subcat ` D ) )
3		eqid	\|- ( Homf ` D ) = ( Homf ` D )
4	2 3	subcssc	\|- ( J e. ( Subcat ` D ) -> J C_cat ( Homf ` D ) )
5		eqid	\|- ( Base ` C ) = ( Base ` C )
6		subcrcl	\|- ( H e. ( Subcat ` C ) -> C e. Cat )
7		id	\|- ( H e. ( Subcat ` C ) -> H e. ( Subcat ` C ) )
8		eqidd	\|- ( H e. ( Subcat ` C ) -> dom dom H = dom dom H )
9	7 8	subcfn	\|- ( H e. ( Subcat ` C ) -> H Fn ( dom dom H X. dom dom H ) )
10	7 9 5	subcss1	\|- ( H e. ( Subcat ` C ) -> dom dom H C_ ( Base ` C ) )
11	1 5 6 9 10	reschomf	\|- ( H e. ( Subcat ` C ) -> H = ( Homf ` D ) )
12	11	breq2d	\|- ( H e. ( Subcat ` C ) -> ( J C_cat H <-> J C_cat ( Homf ` D ) ) )
13	4 12	syl5ibr	\|- ( H e. ( Subcat ` C ) -> ( J e. ( Subcat ` D ) -> J C_cat H ) )
14	13	pm4.71rd	\|- ( H e. ( Subcat ` C ) -> ( J e. ( Subcat ` D ) <-> ( J C_cat H /\ J e. ( Subcat ` D ) ) ) )
15		simpr	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> J C_cat H )
16		simpl	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> H e. ( Subcat ` C ) )
17		eqid	\|- ( Homf ` C ) = ( Homf ` C )
18	16 17	subcssc	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> H C_cat ( Homf ` C ) )
19		ssctr	\|- ( ( J C_cat H /\ H C_cat ( Homf ` C ) ) -> J C_cat ( Homf ` C ) )
20	15 18 19	syl2anc	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> J C_cat ( Homf ` C ) )
21	12	biimpa	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> J C_cat ( Homf ` D ) )
22	20 21	2thd	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> ( J C_cat ( Homf ` C ) <-> J C_cat ( Homf ` D ) ) )
23	16	adantr	\|- ( ( ( H e. ( Subcat ` C ) /\ J C_cat H ) /\ x e. dom dom J ) -> H e. ( Subcat ` C ) )
24	9	adantr	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> H Fn ( dom dom H X. dom dom H ) )
25	24	adantr	\|- ( ( ( H e. ( Subcat ` C ) /\ J C_cat H ) /\ x e. dom dom J ) -> H Fn ( dom dom H X. dom dom H ) )
26		eqid	\|- ( Id ` C ) = ( Id ` C )
27		eqidd	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> dom dom J = dom dom J )
28	15 27	sscfn1	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> J Fn ( dom dom J X. dom dom J ) )
29	28 24 15	ssc1	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> dom dom J C_ dom dom H )
30	29	sselda	\|- ( ( ( H e. ( Subcat ` C ) /\ J C_cat H ) /\ x e. dom dom J ) -> x e. dom dom H )
31	1 23 25 26 30	subcid	\|- ( ( ( H e. ( Subcat ` C ) /\ J C_cat H ) /\ x e. dom dom J ) -> ( ( Id ` C ) ` x ) = ( ( Id ` D ) ` x ) )
32	31	eleq1d	\|- ( ( ( H e. ( Subcat ` C ) /\ J C_cat H ) /\ x e. dom dom J ) -> ( ( ( Id ` C ) ` x ) e. ( x J x ) <-> ( ( Id ` D ) ` x ) e. ( x J x ) ) )
33	32	ralbidva	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> ( A. x e. dom dom J ( ( Id ` C ) ` x ) e. ( x J x ) <-> A. x e. dom dom J ( ( Id ` D ) ` x ) e. ( x J x ) ) )
34	1	oveq1i	\|- ( D \|`cat J ) = ( ( C \|`cat H ) \|`cat J )
35	6	adantr	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> C e. Cat )
36		dmexg	\|- ( H e. ( Subcat ` C ) -> dom H e. _V )
37	36	dmexd	\|- ( H e. ( Subcat ` C ) -> dom dom H e. _V )
38	37	adantr	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> dom dom H e. _V )
39	35 24 28 38 29	rescabs	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> ( ( C \|`cat H ) \|`cat J ) = ( C \|`cat J ) )
40	34 39	syl5req	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> ( C \|`cat J ) = ( D \|`cat J ) )
41	40	eleq1d	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> ( ( C \|`cat J ) e. Cat <-> ( D \|`cat J ) e. Cat ) )
42	22 33 41	3anbi123d	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> ( ( J C_cat ( Homf ` C ) /\ A. x e. dom dom J ( ( Id ` C ) ` x ) e. ( x J x ) /\ ( C \|`cat J ) e. Cat ) <-> ( J C_cat ( Homf ` D ) /\ A. x e. dom dom J ( ( Id ` D ) ` x ) e. ( x J x ) /\ ( D \|`cat J ) e. Cat ) ) )
43		eqid	\|- ( C \|`cat J ) = ( C \|`cat J )
44	17 26 43 35 28	issubc3	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> ( J e. ( Subcat ` C ) <-> ( J C_cat ( Homf ` C ) /\ A. x e. dom dom J ( ( Id ` C ) ` x ) e. ( x J x ) /\ ( C \|`cat J ) e. Cat ) ) )
45		eqid	\|- ( Id ` D ) = ( Id ` D )
46		eqid	\|- ( D \|`cat J ) = ( D \|`cat J )
47	1 7	subccat	\|- ( H e. ( Subcat ` C ) -> D e. Cat )
48	47	adantr	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> D e. Cat )
49	3 45 46 48 28	issubc3	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> ( J e. ( Subcat ` D ) <-> ( J C_cat ( Homf ` D ) /\ A. x e. dom dom J ( ( Id ` D ) ` x ) e. ( x J x ) /\ ( D \|`cat J ) e. Cat ) ) )
50	42 44 49	3bitr4rd	\|- ( ( H e. ( Subcat ` C ) /\ J C_cat H ) -> ( J e. ( Subcat ` D ) <-> J e. ( Subcat ` C ) ) )
51	50	pm5.32da	\|- ( H e. ( Subcat ` C ) -> ( ( J C_cat H /\ J e. ( Subcat ` D ) ) <-> ( J C_cat H /\ J e. ( Subcat ` C ) ) ) )
52	14 51	bitrd	\|- ( H e. ( Subcat ` C ) -> ( J e. ( Subcat ` D ) <-> ( J C_cat H /\ J e. ( Subcat ` C ) ) ) )
53	52	biancomd	\|- ( H e. ( Subcat ` C ) -> ( J e. ( Subcat ` D ) <-> ( J e. ( Subcat ` C ) /\ J C_cat H ) ) )

Metamath Proof Explorer

Theorem subsubc

Proof