prdsco

Description: Structure product composition operation. (Contributed by Mario Carneiro, 7-Jan-2017) (Revised by Thierry Arnoux, 16-Jun-2019) (Revised by Zhi Wang, 18-Aug-2024)

	Ref	Expression
Hypotheses	prdsbas.p	\|- P = ( S Xs_ R )
	prdsbas.s	\|- ( ph -> S e. V )
	prdsbas.r	\|- ( ph -> R e. W )
	prdsbas.b	\|- B = ( Base ` P )
	prdsbas.i	\|- ( ph -> dom R = I )
	prdshom.h	\|- H = ( Hom ` P )
	prdsco.o	\|- .xb = ( comp ` P )
Assertion	prdsco	\|- ( ph -> .xb = ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) )

Proof

Step	Hyp	Ref	Expression
1		prdsbas.p	\|- P = ( S Xs_ R )
2		prdsbas.s	\|- ( ph -> S e. V )
3		prdsbas.r	\|- ( ph -> R e. W )
4		prdsbas.b	\|- B = ( Base ` P )
5		prdsbas.i	\|- ( ph -> dom R = I )
6		prdshom.h	\|- H = ( Hom ` P )
7		prdsco.o	\|- .xb = ( comp ` P )
8		eqid	\|- ( Base ` S ) = ( Base ` S )
9	1 2 3 4 5	prdsbas	\|- ( ph -> B = X_ x e. I ( Base ` ( R ` x ) ) )
10		eqid	\|- ( +g ` P ) = ( +g ` P )
11	1 2 3 4 5 10	prdsplusg	\|- ( ph -> ( +g ` P ) = ( f e. B , g e. B \|-> ( x e. I \|-> ( ( f ` x ) ( +g ` ( R ` x ) ) ( g ` x ) ) ) ) )
12		eqid	\|- ( .r ` P ) = ( .r ` P )
13	1 2 3 4 5 12	prdsmulr	\|- ( ph -> ( .r ` P ) = ( f e. B , g e. B \|-> ( x e. I \|-> ( ( f ` x ) ( .r ` ( R ` x ) ) ( g ` x ) ) ) ) )
14		eqid	\|- ( .s ` P ) = ( .s ` P )
15	1 2 3 4 5 8 14	prdsvsca	\|- ( ph -> ( .s ` P ) = ( f e. ( Base ` S ) , g e. B \|-> ( x e. I \|-> ( f ( .s ` ( R ` x ) ) ( g ` x ) ) ) ) )
16		eqidd	\|- ( ph -> ( f e. B , g e. B \|-> ( S gsum ( x e. I \|-> ( ( f ` x ) ( .i ` ( R ` x ) ) ( g ` x ) ) ) ) ) = ( f e. B , g e. B \|-> ( S gsum ( x e. I \|-> ( ( f ` x ) ( .i ` ( R ` x ) ) ( g ` x ) ) ) ) ) )
17		eqid	\|- ( TopSet ` P ) = ( TopSet ` P )
18	1 2 3 4 5 17	prdstset	\|- ( ph -> ( TopSet ` P ) = ( Xt_ ` ( TopOpen o. R ) ) )
19		eqid	\|- ( le ` P ) = ( le ` P )
20	1 2 3 4 5 19	prdsle	\|- ( ph -> ( le ` P ) = { <. f , g >. \| ( { f , g } C_ B /\ A. x e. I ( f ` x ) ( le ` ( R ` x ) ) ( g ` x ) ) } )
21		eqid	\|- ( dist ` P ) = ( dist ` P )
22	1 2 3 4 5 21	prdsds	\|- ( ph -> ( dist ` P ) = ( f e. B , g e. B \|-> sup ( ( ran ( x e. I \|-> ( ( f ` x ) ( dist ` ( R ` x ) ) ( g ` x ) ) ) u. { 0 } ) , RR* , < ) ) )
23	1 2 3 4 5 6	prdshom	\|- ( ph -> H = ( f e. B , g e. B \|-> X_ x e. I ( ( f ` x ) ( Hom ` ( R ` x ) ) ( g ` x ) ) ) )
24		eqidd	\|- ( ph -> ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) = ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) )
25	1 8 5 9 11 13 15 16 18 20 22 23 24 2 3	prdsval	\|- ( ph -> P = ( ( { <. ( Base ` ndx ) , B >. , <. ( +g ` ndx ) , ( +g ` P ) >. , <. ( .r ` ndx ) , ( .r ` P ) >. } u. { <. ( Scalar ` ndx ) , S >. , <. ( .s ` ndx ) , ( .s ` P ) >. , <. ( .i ` ndx ) , ( f e. B , g e. B \|-> ( S gsum ( x e. I \|-> ( ( f ` x ) ( .i ` ( R ` x ) ) ( g ` x ) ) ) ) ) >. } ) u. ( { <. ( TopSet ` ndx ) , ( TopSet ` P ) >. , <. ( le ` ndx ) , ( le ` P ) >. , <. ( dist ` ndx ) , ( dist ` P ) >. } u. { <. ( Hom ` ndx ) , H >. , <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. } ) ) )
26		ccoid	\|- comp = Slot ( comp ` ndx )
27	4	fvexi	\|- B e. _V
28	27 27	xpex	\|- ( B X. B ) e. _V
29	28 27	mpoex	\|- ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) e. _V
30	29	a1i	\|- ( ph -> ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) e. _V )
31		snsspr2	\|- { <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. } C_ { <. ( Hom ` ndx ) , H >. , <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. }
32		ssun2	\|- { <. ( Hom ` ndx ) , H >. , <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. } C_ ( { <. ( TopSet ` ndx ) , ( TopSet ` P ) >. , <. ( le ` ndx ) , ( le ` P ) >. , <. ( dist ` ndx ) , ( dist ` P ) >. } u. { <. ( Hom ` ndx ) , H >. , <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. } )
33	31 32	sstri	\|- { <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. } C_ ( { <. ( TopSet ` ndx ) , ( TopSet ` P ) >. , <. ( le ` ndx ) , ( le ` P ) >. , <. ( dist ` ndx ) , ( dist ` P ) >. } u. { <. ( Hom ` ndx ) , H >. , <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. } )
34		ssun2	\|- ( { <. ( TopSet ` ndx ) , ( TopSet ` P ) >. , <. ( le ` ndx ) , ( le ` P ) >. , <. ( dist ` ndx ) , ( dist ` P ) >. } u. { <. ( Hom ` ndx ) , H >. , <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. } ) C_ ( ( { <. ( Base ` ndx ) , B >. , <. ( +g ` ndx ) , ( +g ` P ) >. , <. ( .r ` ndx ) , ( .r ` P ) >. } u. { <. ( Scalar ` ndx ) , S >. , <. ( .s ` ndx ) , ( .s ` P ) >. , <. ( .i ` ndx ) , ( f e. B , g e. B \|-> ( S gsum ( x e. I \|-> ( ( f ` x ) ( .i ` ( R ` x ) ) ( g ` x ) ) ) ) ) >. } ) u. ( { <. ( TopSet ` ndx ) , ( TopSet ` P ) >. , <. ( le ` ndx ) , ( le ` P ) >. , <. ( dist ` ndx ) , ( dist ` P ) >. } u. { <. ( Hom ` ndx ) , H >. , <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. } ) )
35	33 34	sstri	\|- { <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. } C_ ( ( { <. ( Base ` ndx ) , B >. , <. ( +g ` ndx ) , ( +g ` P ) >. , <. ( .r ` ndx ) , ( .r ` P ) >. } u. { <. ( Scalar ` ndx ) , S >. , <. ( .s ` ndx ) , ( .s ` P ) >. , <. ( .i ` ndx ) , ( f e. B , g e. B \|-> ( S gsum ( x e. I \|-> ( ( f ` x ) ( .i ` ( R ` x ) ) ( g ` x ) ) ) ) ) >. } ) u. ( { <. ( TopSet ` ndx ) , ( TopSet ` P ) >. , <. ( le ` ndx ) , ( le ` P ) >. , <. ( dist ` ndx ) , ( dist ` P ) >. } u. { <. ( Hom ` ndx ) , H >. , <. ( comp ` ndx ) , ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) >. } ) )
36	25 7 26 30 35	prdsvallem	\|- ( ph -> .xb = ( a e. ( B X. B ) , c e. B \|-> ( d e. ( ( 2nd ` a ) H c ) , e e. ( H ` a ) \|-> ( x e. I \|-> ( ( d ` x ) ( <. ( ( 1st ` a ) ` x ) , ( ( 2nd ` a ) ` x ) >. ( comp ` ( R ` x ) ) ( c ` x ) ) ( e ` x ) ) ) ) ) )

Metamath Proof Explorer

Theorem prdsco

Proof