reofld

Description: The real numbers form an ordered field. (Contributed by Thierry Arnoux, 21-Jan-2018)

		Ref	Expression
	Assertion	reofld	$⊢ ℝ_{fld} \in oField$

Proof

Step	Hyp	Ref	Expression
1		refld	$⊢ ℝ_{fld} \in Field$
2		isfld	$⊢ ℝ_{fld} \in Field \leftrightarrow (ℝ_{fld} \in DivRing \land ℝ_{fld} \in CRing)$
3	2	simplbi	$⊢ ℝ_{fld} \in Field \to ℝ_{fld} \in DivRing$
4		drngring	$⊢ ℝ_{fld} \in DivRing \to ℝ_{fld} \in Ring$
5	1 3 4	mp2b	$⊢ ℝ_{fld} \in Ring$
6		ringgrp	$⊢ ℝ_{fld} \in Ring \to ℝ_{fld} \in Grp$
7	5 6	ax-mp	$⊢ ℝ_{fld} \in Grp$
8		grpmnd	$⊢ ℝ_{fld} \in Grp \to ℝ_{fld} \in Mnd$
9	7 8	ax-mp	$⊢ ℝ_{fld} \in Mnd$
10		retos	$⊢ ℝ_{fld} \in Toset$
11		simpl	$⊢ (a \in ℝ \land (b \in ℝ \land c \in ℝ \land a \leq b)) \to a \in ℝ$
12		simpr1	$⊢ (a \in ℝ \land (b \in ℝ \land c \in ℝ \land a \leq b)) \to b \in ℝ$
13		simpr2	$⊢ (a \in ℝ \land (b \in ℝ \land c \in ℝ \land a \leq b)) \to c \in ℝ$
14		simpr3	$⊢ (a \in ℝ \land (b \in ℝ \land c \in ℝ \land a \leq b)) \to a \leq b$
15	11 12 13 14	leadd1dd	$⊢ (a \in ℝ \land (b \in ℝ \land c \in ℝ \land a \leq b)) \to a + c \leq b + c$
16	15	3anassrs	$⊢ (((a \in ℝ \land b \in ℝ) \land c \in ℝ) \land a \leq b) \to a + c \leq b + c$
17	16	ex	$⊢ ((a \in ℝ \land b \in ℝ) \land c \in ℝ) \to (a \leq b \to a + c \leq b + c)$
18	17	3impa	$⊢ (a \in ℝ \land b \in ℝ \land c \in ℝ) \to (a \leq b \to a + c \leq b + c)$
19	18	rgen3	$⊢ \forall a \in ℝ \forall b \in ℝ \forall c \in ℝ (a \leq b \to a + c \leq b + c)$
20		rebase	$⊢ ℝ = {Base}_{ℝ_{fld}}$
21		replusg	$⊢ + = +_{ℝ_{fld}}$
22		rele2	$⊢ \leq = \leq_{ℝ_{fld}}$
23	20 21 22	isomnd	$⊢ ℝ_{fld} \in oMnd \leftrightarrow (ℝ_{fld} \in Mnd \land ℝ_{fld} \in Toset \land \forall a \in ℝ \forall b \in ℝ \forall c \in ℝ (a \leq b \to a + c \leq b + c))$
24	9 10 19 23	mpbir3an	$⊢ ℝ_{fld} \in oMnd$
25		isogrp	$⊢ ℝ_{fld} \in oGrp \leftrightarrow (ℝ_{fld} \in Grp \land ℝ_{fld} \in oMnd)$
26	7 24 25	mpbir2an	$⊢ ℝ_{fld} \in oGrp$
27		mulge0	$⊢ ((a \in ℝ \land 0 \leq a) \land (b \in ℝ \land 0 \leq b)) \to 0 \leq a b$
28	27	an4s	$⊢ ((a \in ℝ \land b \in ℝ) \land (0 \leq a \land 0 \leq b)) \to 0 \leq a b$
29	28	ex	$⊢ (a \in ℝ \land b \in ℝ) \to ((0 \leq a \land 0 \leq b) \to 0 \leq a b)$
30	29	rgen2	$⊢ \forall a \in ℝ \forall b \in ℝ ((0 \leq a \land 0 \leq b) \to 0 \leq a b)$
31		re0g	$⊢ 0 = 0_{ℝ_{fld}}$
32		remulr	$⊢ \times = \cdot_{ℝ_{fld}}$
33	20 31 32 22	isorng	$⊢ ℝ_{fld} \in oRing \leftrightarrow (ℝ_{fld} \in Ring \land ℝ_{fld} \in oGrp \land \forall a \in ℝ \forall b \in ℝ ((0 \leq a \land 0 \leq b) \to 0 \leq a b))$
34	5 26 30 33	mpbir3an	$⊢ ℝ_{fld} \in oRing$
35		isofld	$⊢ ℝ_{fld} \in oField \leftrightarrow (ℝ_{fld} \in Field \land ℝ_{fld} \in oRing)$
36	1 34 35	mpbir2an	$⊢ ℝ_{fld} \in oField$

Metamath Proof Explorer

Theorem reofld

Proof