lnopl

Description: Basic linearity property of a linear Hilbert space operator. (Contributed by NM, 22-Jan-2006) (New usage is discouraged.)

		Ref	Expression
	Assertion	lnopl	\|- ( ( ( T e. LinOp /\ A e. CC ) /\ ( B e. ~H /\ C e. ~H ) ) -> ( T ` ( ( A .h B ) +h C ) ) = ( ( A .h ( T ` B ) ) +h ( T ` C ) ) )

Proof

Step	Hyp	Ref	Expression
1		ellnop	\|- ( T e. LinOp <-> ( T : ~H --> ~H /\ A. x e. CC A. y e. ~H A. z e. ~H ( T ` ( ( x .h y ) +h z ) ) = ( ( x .h ( T ` y ) ) +h ( T ` z ) ) ) )
2	1	simprbi	\|- ( T e. LinOp -> A. x e. CC A. y e. ~H A. z e. ~H ( T ` ( ( x .h y ) +h z ) ) = ( ( x .h ( T ` y ) ) +h ( T ` z ) ) )
3		oveq1	\|- ( x = A -> ( x .h y ) = ( A .h y ) )
4	3	fvoveq1d	\|- ( x = A -> ( T ` ( ( x .h y ) +h z ) ) = ( T ` ( ( A .h y ) +h z ) ) )
5		oveq1	\|- ( x = A -> ( x .h ( T ` y ) ) = ( A .h ( T ` y ) ) )
6	5	oveq1d	\|- ( x = A -> ( ( x .h ( T ` y ) ) +h ( T ` z ) ) = ( ( A .h ( T ` y ) ) +h ( T ` z ) ) )
7	4 6	eqeq12d	\|- ( x = A -> ( ( T ` ( ( x .h y ) +h z ) ) = ( ( x .h ( T ` y ) ) +h ( T ` z ) ) <-> ( T ` ( ( A .h y ) +h z ) ) = ( ( A .h ( T ` y ) ) +h ( T ` z ) ) ) )
8		oveq2	\|- ( y = B -> ( A .h y ) = ( A .h B ) )
9	8	fvoveq1d	\|- ( y = B -> ( T ` ( ( A .h y ) +h z ) ) = ( T ` ( ( A .h B ) +h z ) ) )
10		fveq2	\|- ( y = B -> ( T ` y ) = ( T ` B ) )
11	10	oveq2d	\|- ( y = B -> ( A .h ( T ` y ) ) = ( A .h ( T ` B ) ) )
12	11	oveq1d	\|- ( y = B -> ( ( A .h ( T ` y ) ) +h ( T ` z ) ) = ( ( A .h ( T ` B ) ) +h ( T ` z ) ) )
13	9 12	eqeq12d	\|- ( y = B -> ( ( T ` ( ( A .h y ) +h z ) ) = ( ( A .h ( T ` y ) ) +h ( T ` z ) ) <-> ( T ` ( ( A .h B ) +h z ) ) = ( ( A .h ( T ` B ) ) +h ( T ` z ) ) ) )
14		oveq2	\|- ( z = C -> ( ( A .h B ) +h z ) = ( ( A .h B ) +h C ) )
15	14	fveq2d	\|- ( z = C -> ( T ` ( ( A .h B ) +h z ) ) = ( T ` ( ( A .h B ) +h C ) ) )
16		fveq2	\|- ( z = C -> ( T ` z ) = ( T ` C ) )
17	16	oveq2d	\|- ( z = C -> ( ( A .h ( T ` B ) ) +h ( T ` z ) ) = ( ( A .h ( T ` B ) ) +h ( T ` C ) ) )
18	15 17	eqeq12d	\|- ( z = C -> ( ( T ` ( ( A .h B ) +h z ) ) = ( ( A .h ( T ` B ) ) +h ( T ` z ) ) <-> ( T ` ( ( A .h B ) +h C ) ) = ( ( A .h ( T ` B ) ) +h ( T ` C ) ) ) )
19	7 13 18	rspc3v	\|- ( ( A e. CC /\ B e. ~H /\ C e. ~H ) -> ( A. x e. CC A. y e. ~H A. z e. ~H ( T ` ( ( x .h y ) +h z ) ) = ( ( x .h ( T ` y ) ) +h ( T ` z ) ) -> ( T ` ( ( A .h B ) +h C ) ) = ( ( A .h ( T ` B ) ) +h ( T ` C ) ) ) )
20	2 19	syl5	\|- ( ( A e. CC /\ B e. ~H /\ C e. ~H ) -> ( T e. LinOp -> ( T ` ( ( A .h B ) +h C ) ) = ( ( A .h ( T ` B ) ) +h ( T ` C ) ) ) )
21	20	3expb	\|- ( ( A e. CC /\ ( B e. ~H /\ C e. ~H ) ) -> ( T e. LinOp -> ( T ` ( ( A .h B ) +h C ) ) = ( ( A .h ( T ` B ) ) +h ( T ` C ) ) ) )
22	21	impcom	\|- ( ( T e. LinOp /\ ( A e. CC /\ ( B e. ~H /\ C e. ~H ) ) ) -> ( T ` ( ( A .h B ) +h C ) ) = ( ( A .h ( T ` B ) ) +h ( T ` C ) ) )
23	22	anassrs	\|- ( ( ( T e. LinOp /\ A e. CC ) /\ ( B e. ~H /\ C e. ~H ) ) -> ( T ` ( ( A .h B ) +h C ) ) = ( ( A .h ( T ` B ) ) +h ( T ` C ) ) )

Metamath Proof Explorer

Theorem lnopl

Proof