rrxsca

Description: The field of real numbers is the scalar field of the generalized real Euclidean space. (Contributed by AV, 15-Jan-2023)

		Ref	Expression
	Hypothesis	rrxsca.r	$⊢ H = I$
	Assertion	rrxsca	$⊢ I \in V \to Scalar (H) = ℝ_{fld}$

Proof

Step	Hyp	Ref	Expression
1		rrxsca.r	$⊢ H = I$
2		eqid	$⊢ {Base}_{H} = {Base}_{H}$
3	1 2	rrxprds	$⊢ I \in V \to H = toCPreHil ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})$
4	3	fveq2d	$⊢ I \in V \to Scalar (H) = Scalar (toCPreHil ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}))$
5		fvex	$⊢ {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} \in V$
6	5	mptex	$⊢ (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x}) \in V$
7		eqid	$⊢ ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) toNrmGrp (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x}) = ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) toNrmGrp (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x})$
8		eqid	$⊢ Scalar ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) = Scalar ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})$
9	7 8	tngsca	$⊢ (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x}) \in V \to Scalar ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) = Scalar (((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) toNrmGrp (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x}))$
10	9	eqcomd	$⊢ (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x}) \in V \to Scalar (((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) toNrmGrp (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x})) = Scalar ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})$
11	6 10	mp1i	$⊢ I \in V \to Scalar (((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) toNrmGrp (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x})) = Scalar ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})$
12		eqid	$⊢ toCPreHil ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) = toCPreHil ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})$
13		eqid	$⊢ {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} = {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})}$
14		eqid	$⊢ \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) = \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})$
15	12 13 14	tcphval	$⊢ toCPreHil ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) = ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) toNrmGrp (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x})$
16	15	fveq2i	$⊢ Scalar (toCPreHil ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})) = Scalar (((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) toNrmGrp (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x}))$
17	16	a1i	$⊢ I \in V \to Scalar (toCPreHil ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})) = Scalar (((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) toNrmGrp (x \in {Base}_{((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})} ⟼ \sqrt{x \cdot_{𝑖} ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}) x}))$
18		eqid	$⊢ ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\}) = ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})$
19		refld	$⊢ ℝ_{fld} \in Field$
20	19	a1i	$⊢ I \in V \to ℝ_{fld} \in Field$
21		id	$⊢ I \in V \to I \in V$
22		snex	$⊢ \{subringAlg (ℝ_{fld}) (ℝ)\} \in V$
23	22	a1i	$⊢ I \in V \to \{subringAlg (ℝ_{fld}) (ℝ)\} \in V$
24	21 23	xpexd	$⊢ I \in V \to I \times \{subringAlg (ℝ_{fld}) (ℝ)\} \in V$
25	18 20 24	prdssca	$⊢ I \in V \to ℝ_{fld} = Scalar (ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\}))$
26		fvex	$⊢ {Base}_{H} \in V$
27		eqid	$⊢ (ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H} = (ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H}$
28		eqid	$⊢ Scalar (ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) = Scalar (ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\}))$
29	27 28	resssca	$⊢ {Base}_{H} \in V \to Scalar (ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) = Scalar ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})$
30	26 29	mp1i	$⊢ I \in V \to Scalar (ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) = Scalar ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})$
31	25 30	eqtrd	$⊢ I \in V \to ℝ_{fld} = Scalar ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})$
32	11 17 31	3eqtr4d	$⊢ I \in V \to Scalar (toCPreHil ((ℝ_{fld} ⨉_{𝑠} (I \times \{subringAlg (ℝ_{fld}) (ℝ)\})) ↾_{𝑠} {Base}_{H})) = ℝ_{fld}$
33	4 32	eqtrd	$⊢ I \in V \to Scalar (H) = ℝ_{fld}$

Metamath Proof Explorer

Theorem rrxsca

Proof