psrsca

Description: The scalar field of the multivariate power series structure. (Contributed by Mario Carneiro, 28-Dec-2014)

	Ref	Expression
Hypotheses	psrsca.s	\|- S = ( I mPwSer R )
	psrsca.i	\|- ( ph -> I e. V )
	psrsca.r	\|- ( ph -> R e. W )
Assertion	psrsca	\|- ( ph -> R = ( Scalar ` S ) )

Proof

Step	Hyp	Ref	Expression
1		psrsca.s	\|- S = ( I mPwSer R )
2		psrsca.i	\|- ( ph -> I e. V )
3		psrsca.r	\|- ( ph -> R e. W )
4		psrvalstr	\|- ( { <. ( Base ` ndx ) , ( Base ` S ) >. , <. ( +g ` ndx ) , ( +g ` S ) >. , <. ( .r ` ndx ) , ( .r ` S ) >. } u. { <. ( Scalar ` ndx ) , R >. , <. ( .s ` ndx ) , ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) ) >. , <. ( TopSet ` ndx ) , ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) >. } ) Struct <. 1 , 9 >.
5		scaid	\|- Scalar = Slot ( Scalar ` ndx )
6		snsstp1	\|- { <. ( Scalar ` ndx ) , R >. } C_ { <. ( Scalar ` ndx ) , R >. , <. ( .s ` ndx ) , ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) ) >. , <. ( TopSet ` ndx ) , ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) >. }
7		ssun2	\|- { <. ( Scalar ` ndx ) , R >. , <. ( .s ` ndx ) , ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) ) >. , <. ( TopSet ` ndx ) , ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) >. } C_ ( { <. ( Base ` ndx ) , ( Base ` S ) >. , <. ( +g ` ndx ) , ( +g ` S ) >. , <. ( .r ` ndx ) , ( .r ` S ) >. } u. { <. ( Scalar ` ndx ) , R >. , <. ( .s ` ndx ) , ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) ) >. , <. ( TopSet ` ndx ) , ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) >. } )
8	6 7	sstri	\|- { <. ( Scalar ` ndx ) , R >. } C_ ( { <. ( Base ` ndx ) , ( Base ` S ) >. , <. ( +g ` ndx ) , ( +g ` S ) >. , <. ( .r ` ndx ) , ( .r ` S ) >. } u. { <. ( Scalar ` ndx ) , R >. , <. ( .s ` ndx ) , ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) ) >. , <. ( TopSet ` ndx ) , ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) >. } )
9	4 5 8	strfv	\|- ( R e. W -> R = ( Scalar ` ( { <. ( Base ` ndx ) , ( Base ` S ) >. , <. ( +g ` ndx ) , ( +g ` S ) >. , <. ( .r ` ndx ) , ( .r ` S ) >. } u. { <. ( Scalar ` ndx ) , R >. , <. ( .s ` ndx ) , ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) ) >. , <. ( TopSet ` ndx ) , ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) >. } ) ) )
10	3 9	syl	\|- ( ph -> R = ( Scalar ` ( { <. ( Base ` ndx ) , ( Base ` S ) >. , <. ( +g ` ndx ) , ( +g ` S ) >. , <. ( .r ` ndx ) , ( .r ` S ) >. } u. { <. ( Scalar ` ndx ) , R >. , <. ( .s ` ndx ) , ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) ) >. , <. ( TopSet ` ndx ) , ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) >. } ) ) )
11		eqid	\|- ( Base ` R ) = ( Base ` R )
12		eqid	\|- ( +g ` R ) = ( +g ` R )
13		eqid	\|- ( .r ` R ) = ( .r ` R )
14		eqid	\|- ( TopOpen ` R ) = ( TopOpen ` R )
15		eqid	\|- { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } = { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin }
16		eqid	\|- ( Base ` S ) = ( Base ` S )
17	1 11 15 16 2	psrbas	\|- ( ph -> ( Base ` S ) = ( ( Base ` R ) ^m { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } ) )
18		eqid	\|- ( +g ` S ) = ( +g ` S )
19	1 16 12 18	psrplusg	\|- ( +g ` S ) = ( oF ( +g ` R ) \|` ( ( Base ` S ) X. ( Base ` S ) ) )
20		eqid	\|- ( .r ` S ) = ( .r ` S )
21	1 16 13 20 15	psrmulr	\|- ( .r ` S ) = ( f e. ( Base ` S ) , z e. ( Base ` S ) \|-> ( w e. { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } \|-> ( R gsum ( x e. { y e. { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } \| y oR <_ w } \|-> ( ( f ` x ) ( .r ` R ) ( z ` ( w oF - x ) ) ) ) ) ) )
22		eqid	\|- ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) ) = ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) )
23		eqidd	\|- ( ph -> ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) = ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) )
24	1 11 12 13 14 15 17 19 21 22 23 2 3	psrval	\|- ( ph -> S = ( { <. ( Base ` ndx ) , ( Base ` S ) >. , <. ( +g ` ndx ) , ( +g ` S ) >. , <. ( .r ` ndx ) , ( .r ` S ) >. } u. { <. ( Scalar ` ndx ) , R >. , <. ( .s ` ndx ) , ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) ) >. , <. ( TopSet ` ndx ) , ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) >. } ) )
25	24	fveq2d	\|- ( ph -> ( Scalar ` S ) = ( Scalar ` ( { <. ( Base ` ndx ) , ( Base ` S ) >. , <. ( +g ` ndx ) , ( +g ` S ) >. , <. ( .r ` ndx ) , ( .r ` S ) >. } u. { <. ( Scalar ` ndx ) , R >. , <. ( .s ` ndx ) , ( x e. ( Base ` R ) , f e. ( Base ` S ) \|-> ( ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { x } ) oF ( .r ` R ) f ) ) >. , <. ( TopSet ` ndx ) , ( Xt_ ` ( { h e. ( NN0 ^m I ) \| ( `' h " NN ) e. Fin } X. { ( TopOpen ` R ) } ) ) >. } ) ) )
26	10 25	eqtr4d	\|- ( ph -> R = ( Scalar ` S ) )

Metamath Proof Explorer

Theorem psrsca

Proof