qqhval

Description: Value of the canonical homormorphism from the rational number to a field. (Contributed by Thierry Arnoux, 22-Oct-2017)

	Ref	Expression
Hypotheses	qqhval.1	$⊢ \underset{˙}{\times} = /_{r} (R)$
	qqhval.2	$⊢ \underset{˙}{1} = 1_{R}$
	qqhval.3	$⊢ L = ℤRHom (R)$
Assertion	qqhval	$⊢ R \in V \to ℚHom (R) = ran (x \in ℤ, y \in L^{-1} [Unit (R)] ⟼ ⟨\frac{x}{y}, L (x) \underset{˙}{\times} L (y)⟩)$

Proof

Step	Hyp	Ref	Expression
1		qqhval.1	$⊢ \underset{˙}{\times} = /_{r} (R)$
2		qqhval.2	$⊢ \underset{˙}{1} = 1_{R}$
3		qqhval.3	$⊢ L = ℤRHom (R)$
4		eqidd	$⊢ f = R \to ℤ = ℤ$
5		fveq2	$⊢ f = R \to ℤRHom (f) = ℤRHom (R)$
6	5 3	eqtr4di	$⊢ f = R \to ℤRHom (f) = L$
7	6	cnveqd	$⊢ f = R \to {ℤRHom (f)}^{-1} = L^{-1}$
8		fveq2	$⊢ f = R \to Unit (f) = Unit (R)$
9	7 8	imaeq12d	$⊢ f = R \to {ℤRHom (f)}^{-1} [Unit (f)] = L^{-1} [Unit (R)]$
10		fveq2	$⊢ f = R \to /_{r} (f) = /_{r} (R)$
11	10 1	eqtr4di	$⊢ f = R \to /_{r} (f) = \underset{˙}{\times}$
12	6	fveq1d	$⊢ f = R \to ℤRHom (f) (x) = L (x)$
13	6	fveq1d	$⊢ f = R \to ℤRHom (f) (y) = L (y)$
14	11 12 13	oveq123d	$⊢ f = R \to ℤRHom (f) (x) /_{r} (f) ℤRHom (f) (y) = L (x) \underset{˙}{\times} L (y)$
15	14	opeq2d	$⊢ f = R \to ⟨\frac{x}{y}, ℤRHom (f) (x) /_{r} (f) ℤRHom (f) (y)⟩ = ⟨\frac{x}{y}, L (x) \underset{˙}{\times} L (y)⟩$
16	4 9 15	mpoeq123dv	$⊢ f = R \to (x \in ℤ, y \in {ℤRHom (f)}^{-1} [Unit (f)] ⟼ ⟨\frac{x}{y}, ℤRHom (f) (x) /_{r} (f) ℤRHom (f) (y)⟩) = (x \in ℤ, y \in L^{-1} [Unit (R)] ⟼ ⟨\frac{x}{y}, L (x) \underset{˙}{\times} L (y)⟩)$
17	16	rneqd	$⊢ f = R \to ran (x \in ℤ, y \in {ℤRHom (f)}^{-1} [Unit (f)] ⟼ ⟨\frac{x}{y}, ℤRHom (f) (x) /_{r} (f) ℤRHom (f) (y)⟩) = ran (x \in ℤ, y \in L^{-1} [Unit (R)] ⟼ ⟨\frac{x}{y}, L (x) \underset{˙}{\times} L (y)⟩)$
18		df-qqh	$⊢ ℚHom = (f \in V ⟼ ran (x \in ℤ, y \in {ℤRHom (f)}^{-1} [Unit (f)] ⟼ ⟨\frac{x}{y}, ℤRHom (f) (x) /_{r} (f) ℤRHom (f) (y)⟩))$
19		zex	$⊢ ℤ \in V$
20	3	fvexi	$⊢ L \in V$
21	20	cnvex	$⊢ L^{-1} \in V$
22		imaexg	$⊢ L^{-1} \in V \to L^{-1} [Unit (R)] \in V$
23	21 22	ax-mp	$⊢ L^{-1} [Unit (R)] \in V$
24	19 23	mpoex	$⊢ (x \in ℤ, y \in L^{-1} [Unit (R)] ⟼ ⟨\frac{x}{y}, L (x) \underset{˙}{\times} L (y)⟩) \in V$
25	24	rnex	$⊢ ran (x \in ℤ, y \in L^{-1} [Unit (R)] ⟼ ⟨\frac{x}{y}, L (x) \underset{˙}{\times} L (y)⟩) \in V$
26	17 18 25	fvmpt	$⊢ R \in V \to ℚHom (R) = ran (x \in ℤ, y \in L^{-1} [Unit (R)] ⟼ ⟨\frac{x}{y}, L (x) \underset{˙}{\times} L (y)⟩)$

Metamath Proof Explorer

Theorem qqhval

Proof