Metamath Proof Explorer

Theorem itgresr

Description: The domain of an integral only matters in its intersection with RR . (Contributed by Mario Carneiro, 29-Jun-2014)

		Ref	Expression
	Assertion	itgresr	\|- S. A B _d x = S. ( A i^i RR ) B _d x

Proof

Step	Hyp	Ref	Expression
1		simpr	\|- ( ( k e. ( 0 ... 3 ) /\ x e. RR ) -> x e. RR )
2	1	biantrud	\|- ( ( k e. ( 0 ... 3 ) /\ x e. RR ) -> ( x e. A <-> ( x e. A /\ x e. RR ) ) )
3		elin	\|- ( x e. ( A i^i RR ) <-> ( x e. A /\ x e. RR ) )
4	2 3	bitr4di	\|- ( ( k e. ( 0 ... 3 ) /\ x e. RR ) -> ( x e. A <-> x e. ( A i^i RR ) ) )
5	4	anbi1d	\|- ( ( k e. ( 0 ... 3 ) /\ x e. RR ) -> ( ( x e. A /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) <-> ( x e. ( A i^i RR ) /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) ) )
6	5	ifbid	\|- ( ( k e. ( 0 ... 3 ) /\ x e. RR ) -> if ( ( x e. A /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) = if ( ( x e. ( A i^i RR ) /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) )
7	6	mpteq2dva	\|- ( k e. ( 0 ... 3 ) -> ( x e. RR \|-> if ( ( x e. A /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) ) = ( x e. RR \|-> if ( ( x e. ( A i^i RR ) /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) ) )
8	7	fveq2d	\|- ( k e. ( 0 ... 3 ) -> ( S.2 ` ( x e. RR \|-> if ( ( x e. A /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) ) ) = ( S.2 ` ( x e. RR \|-> if ( ( x e. ( A i^i RR ) /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) ) ) )
9	8	oveq2d	\|- ( k e. ( 0 ... 3 ) -> ( ( _i ^ k ) x. ( S.2 ` ( x e. RR \|-> if ( ( x e. A /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) ) ) ) = ( ( _i ^ k ) x. ( S.2 ` ( x e. RR \|-> if ( ( x e. ( A i^i RR ) /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) ) ) ) )
10	9	sumeq2i	\|- sum_ k e. ( 0 ... 3 ) ( ( _i ^ k ) x. ( S.2 ` ( x e. RR \|-> if ( ( x e. A /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) ) ) ) = sum_ k e. ( 0 ... 3 ) ( ( _i ^ k ) x. ( S.2 ` ( x e. RR \|-> if ( ( x e. ( A i^i RR ) /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) ) ) )
11		eqid	\|- ( Re ` ( B / ( _i ^ k ) ) ) = ( Re ` ( B / ( _i ^ k ) ) )
12	11	dfitg	\|- S. A B _d x = sum_ k e. ( 0 ... 3 ) ( ( _i ^ k ) x. ( S.2 ` ( x e. RR \|-> if ( ( x e. A /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) ) ) )
13	11	dfitg	\|- S. ( A i^i RR ) B _d x = sum_ k e. ( 0 ... 3 ) ( ( _i ^ k ) x. ( S.2 ` ( x e. RR \|-> if ( ( x e. ( A i^i RR ) /\ 0 <_ ( Re ` ( B / ( _i ^ k ) ) ) ) , ( Re ` ( B / ( _i ^ k ) ) ) , 0 ) ) ) )
14	10 12 13	3eqtr4i	\|- S. A B _d x = S. ( A i^i RR ) B _d x