lnoval

Description: The set of linear operators between two normed complex vector spaces. (Contributed by NM, 6-Nov-2007) (Revised by Mario Carneiro, 16-Nov-2013) (New usage is discouraged.)

	Ref	Expression
Hypotheses	lnoval.1	$⊢ X = BaseSet (U)$
	lnoval.2	$⊢ Y = BaseSet (W)$
	lnoval.3	$⊢ G = +_{v} (U)$
	lnoval.4	$⊢ H = +_{v} (W)$
	lnoval.5	$⊢ R = \cdot_{𝑠OLD} (U)$
	lnoval.6	$⊢ S = \cdot_{𝑠OLD} (W)$
	lnoval.7	$⊢ L = U LnOp W$
Assertion	lnoval	$⊢ (U \in NrmCVec \land W \in NrmCVec) \to L = \{t \in (Y^{X}) \| \forall x \in ℂ \forall y \in X \forall z \in X t ((x R y) G z) = (x S t (y)) H t (z)\}$

Proof

Step	Hyp	Ref	Expression
1		lnoval.1	$⊢ X = BaseSet (U)$
2		lnoval.2	$⊢ Y = BaseSet (W)$
3		lnoval.3	$⊢ G = +_{v} (U)$
4		lnoval.4	$⊢ H = +_{v} (W)$
5		lnoval.5	$⊢ R = \cdot_{𝑠OLD} (U)$
6		lnoval.6	$⊢ S = \cdot_{𝑠OLD} (W)$
7		lnoval.7	$⊢ L = U LnOp W$
8		fveq2	$⊢ u = U \to BaseSet (u) = BaseSet (U)$
9	8 1	eqtr4di	$⊢ u = U \to BaseSet (u) = X$
10	9	oveq2d	$⊢ u = U \to {BaseSet (w)}^{BaseSet (u)} = {BaseSet (w)}^{X}$
11		fveq2	$⊢ u = U \to +_{v} (u) = +_{v} (U)$
12	11 3	eqtr4di	$⊢ u = U \to +_{v} (u) = G$
13		fveq2	$⊢ u = U \to \cdot_{𝑠OLD} (u) = \cdot_{𝑠OLD} (U)$
14	13 5	eqtr4di	$⊢ u = U \to \cdot_{𝑠OLD} (u) = R$
15	14	oveqd	$⊢ u = U \to x \cdot_{𝑠OLD} (u) y = x R y$
16		eqidd	$⊢ u = U \to z = z$
17	12 15 16	oveq123d	$⊢ u = U \to (x \cdot_{𝑠OLD} (u) y) +_{v} (u) z = (x R y) G z$
18	17	fveqeq2d	$⊢ u = U \to (t ((x \cdot_{𝑠OLD} (u) y) +_{v} (u) z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z) \leftrightarrow t ((x R y) G z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z))$
19	9 18	raleqbidv	$⊢ u = U \to (\forall z \in BaseSet (u) t ((x \cdot_{𝑠OLD} (u) y) +_{v} (u) z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z) \leftrightarrow \forall z \in X t ((x R y) G z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z))$
20	9 19	raleqbidv	$⊢ u = U \to (\forall y \in BaseSet (u) \forall z \in BaseSet (u) t ((x \cdot_{𝑠OLD} (u) y) +_{v} (u) z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z) \leftrightarrow \forall y \in X \forall z \in X t ((x R y) G z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z))$
21	20	ralbidv	$⊢ u = U \to (\forall x \in ℂ \forall y \in BaseSet (u) \forall z \in BaseSet (u) t ((x \cdot_{𝑠OLD} (u) y) +_{v} (u) z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z) \leftrightarrow \forall x \in ℂ \forall y \in X \forall z \in X t ((x R y) G z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z))$
22	10 21	rabeqbidv	$⊢ u = U \to \{t \in ({BaseSet (w)}^{BaseSet (u)}) \| \forall x \in ℂ \forall y \in BaseSet (u) \forall z \in BaseSet (u) t ((x \cdot_{𝑠OLD} (u) y) +_{v} (u) z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z)\} = \{t \in ({BaseSet (w)}^{X}) \| \forall x \in ℂ \forall y \in X \forall z \in X t ((x R y) G z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z)\}$
23		fveq2	$⊢ w = W \to BaseSet (w) = BaseSet (W)$
24	23 2	eqtr4di	$⊢ w = W \to BaseSet (w) = Y$
25	24	oveq1d	$⊢ w = W \to {BaseSet (w)}^{X} = Y^{X}$
26		fveq2	$⊢ w = W \to +_{v} (w) = +_{v} (W)$
27	26 4	eqtr4di	$⊢ w = W \to +_{v} (w) = H$
28		fveq2	$⊢ w = W \to \cdot_{𝑠OLD} (w) = \cdot_{𝑠OLD} (W)$
29	28 6	eqtr4di	$⊢ w = W \to \cdot_{𝑠OLD} (w) = S$
30	29	oveqd	$⊢ w = W \to x \cdot_{𝑠OLD} (w) t (y) = x S t (y)$
31		eqidd	$⊢ w = W \to t (z) = t (z)$
32	27 30 31	oveq123d	$⊢ w = W \to (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z) = (x S t (y)) H t (z)$
33	32	eqeq2d	$⊢ w = W \to (t ((x R y) G z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z) \leftrightarrow t ((x R y) G z) = (x S t (y)) H t (z))$
34	33	2ralbidv	$⊢ w = W \to (\forall y \in X \forall z \in X t ((x R y) G z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z) \leftrightarrow \forall y \in X \forall z \in X t ((x R y) G z) = (x S t (y)) H t (z))$
35	34	ralbidv	$⊢ w = W \to (\forall x \in ℂ \forall y \in X \forall z \in X t ((x R y) G z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z) \leftrightarrow \forall x \in ℂ \forall y \in X \forall z \in X t ((x R y) G z) = (x S t (y)) H t (z))$
36	25 35	rabeqbidv	$⊢ w = W \to \{t \in ({BaseSet (w)}^{X}) \| \forall x \in ℂ \forall y \in X \forall z \in X t ((x R y) G z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z)\} = \{t \in (Y^{X}) \| \forall x \in ℂ \forall y \in X \forall z \in X t ((x R y) G z) = (x S t (y)) H t (z)\}$
37		df-lno	$⊢ LnOp = (u \in NrmCVec, w \in NrmCVec ⟼ \{t \in ({BaseSet (w)}^{BaseSet (u)}) \| \forall x \in ℂ \forall y \in BaseSet (u) \forall z \in BaseSet (u) t ((x \cdot_{𝑠OLD} (u) y) +_{v} (u) z) = (x \cdot_{𝑠OLD} (w) t (y)) +_{v} (w) t (z)\})$
38		ovex	$⊢ Y^{X} \in V$
39	38	rabex	$⊢ \{t \in (Y^{X}) \| \forall x \in ℂ \forall y \in X \forall z \in X t ((x R y) G z) = (x S t (y)) H t (z)\} \in V$
40	22 36 37 39	ovmpo	$⊢ (U \in NrmCVec \land W \in NrmCVec) \to U LnOp W = \{t \in (Y^{X}) \| \forall x \in ℂ \forall y \in X \forall z \in X t ((x R y) G z) = (x S t (y)) H t (z)\}$
41	7 40	eqtrid	$⊢ (U \in NrmCVec \land W \in NrmCVec) \to L = \{t \in (Y^{X}) \| \forall x \in ℂ \forall y \in X \forall z \in X t ((x R y) G z) = (x S t (y)) H t (z)\}$

Metamath Proof Explorer

Theorem lnoval

Proof