cnstrcvs

Description: The set of complex numbers is a subcomplex vector space. The vector operation is + , and the scalar product is x. . (Contributed by NM, 5-Nov-2006) (Revised by AV, 20-Sep-2021)

		Ref	Expression
	Hypothesis	cnlmod.w	$⊢ W = \{⟨{Base}_{ndx}, ℂ⟩, ⟨+_{ndx} +⟩\} \cup \{⟨Scalar (ndx), ℂ_{fld}⟩, ⟨\cdot_{ndx} \times⟩\}$
	Assertion	cnstrcvs	$⊢ W \in ℂVec$

Proof

Step	Hyp	Ref	Expression
1		cnlmod.w	$⊢ W = \{⟨{Base}_{ndx}, ℂ⟩, ⟨+_{ndx} +⟩\} \cup \{⟨Scalar (ndx), ℂ_{fld}⟩, ⟨\cdot_{ndx} \times⟩\}$
2	1	cnlmod	$⊢ W \in LMod$
3		cnfldex	$⊢ ℂ_{fld} \in V$
4		cnfldbas	$⊢ ℂ = {Base}_{ℂ_{fld}}$
5	4	ressid	$⊢ ℂ_{fld} \in V \to ℂ_{fld} ↾_{𝑠} ℂ = ℂ_{fld}$
6	3 5	ax-mp	$⊢ ℂ_{fld} ↾_{𝑠} ℂ = ℂ_{fld}$
7	6	eqcomi	$⊢ ℂ_{fld} = ℂ_{fld} ↾_{𝑠} ℂ$
8		id	$⊢ x \in ℂ \to x \in ℂ$
9		addcl	$⊢ (x \in ℂ \land y \in ℂ) \to x + y \in ℂ$
10		negcl	$⊢ x \in ℂ \to - x \in ℂ$
11		ax-1cn	$⊢ 1 \in ℂ$
12		mulcl	$⊢ (x \in ℂ \land y \in ℂ) \to x y \in ℂ$
13	8 9 10 11 12	cnsubrglem	$⊢ ℂ \in SubRing (ℂ_{fld})$
14		qdass	$⊢ \{⟨{Base}_{ndx}, ℂ⟩, ⟨+_{ndx} +⟩\} \cup \{⟨Scalar (ndx), ℂ_{fld}⟩, ⟨\cdot_{ndx} \times⟩\} = \{⟨{Base}_{ndx}, ℂ⟩, ⟨+_{ndx} +⟩, ⟨Scalar (ndx), ℂ_{fld}⟩\} \cup \{⟨\cdot_{ndx} \times⟩\}$
15	1 14	eqtri	$⊢ W = \{⟨{Base}_{ndx}, ℂ⟩, ⟨+_{ndx} +⟩, ⟨Scalar (ndx), ℂ_{fld}⟩\} \cup \{⟨\cdot_{ndx} \times⟩\}$
16	15	lmodsca	$⊢ ℂ_{fld} \in V \to ℂ_{fld} = Scalar (W)$
17	3 16	ax-mp	$⊢ ℂ_{fld} = Scalar (W)$
18	17	isclmi	$⊢ (W \in LMod \land ℂ_{fld} = ℂ_{fld} ↾_{𝑠} ℂ \land ℂ \in SubRing (ℂ_{fld})) \to W \in CMod$
19	2 7 13 18	mp3an	$⊢ W \in CMod$
20		cndrng	$⊢ ℂ_{fld} \in DivRing$
21	17	islvec	$⊢ W \in LVec \leftrightarrow (W \in LMod \land ℂ_{fld} \in DivRing)$
22	2 20 21	mpbir2an	$⊢ W \in LVec$
23	19 22	elini	$⊢ W \in (CMod \cap LVec)$
24		df-cvs	$⊢ ℂVec = CMod \cap LVec$
25	23 24	eleqtrri	$⊢ W \in ℂVec$

Metamath Proof Explorer

Theorem cnstrcvs

Proof