rge0srg

Description: The nonnegative real numbers form a semiring (commutative by subcmn ). (Contributed by Thierry Arnoux, 6-Sep-2018)

		Ref	Expression
	Assertion	rge0srg	\|- ( CCfld \|`s ( 0 [,) +oo ) ) e. SRing

Proof

Step	Hyp	Ref	Expression
1		cnring	\|- CCfld e. Ring
2		ringcmn	\|- ( CCfld e. Ring -> CCfld e. CMnd )
3	1 2	ax-mp	\|- CCfld e. CMnd
4		rege0subm	\|- ( 0 [,) +oo ) e. ( SubMnd ` CCfld )
5		eqid	\|- ( CCfld \|`s ( 0 [,) +oo ) ) = ( CCfld \|`s ( 0 [,) +oo ) )
6	5	submcmn	\|- ( ( CCfld e. CMnd /\ ( 0 [,) +oo ) e. ( SubMnd ` CCfld ) ) -> ( CCfld \|`s ( 0 [,) +oo ) ) e. CMnd )
7	3 4 6	mp2an	\|- ( CCfld \|`s ( 0 [,) +oo ) ) e. CMnd
8		rge0ssre	\|- ( 0 [,) +oo ) C_ RR
9		ax-resscn	\|- RR C_ CC
10	8 9	sstri	\|- ( 0 [,) +oo ) C_ CC
11		1re	\|- 1 e. RR
12		0le1	\|- 0 <_ 1
13		ltpnf	\|- ( 1 e. RR -> 1 < +oo )
14	11 13	ax-mp	\|- 1 < +oo
15		0re	\|- 0 e. RR
16		pnfxr	\|- +oo e. RR*
17		elico2	\|- ( ( 0 e. RR /\ +oo e. RR* ) -> ( 1 e. ( 0 [,) +oo ) <-> ( 1 e. RR /\ 0 <_ 1 /\ 1 < +oo ) ) )
18	15 16 17	mp2an	\|- ( 1 e. ( 0 [,) +oo ) <-> ( 1 e. RR /\ 0 <_ 1 /\ 1 < +oo ) )
19	11 12 14 18	mpbir3an	\|- 1 e. ( 0 [,) +oo )
20		ge0mulcl	\|- ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) -> ( x x. y ) e. ( 0 [,) +oo ) )
21	20	rgen2	\|- A. x e. ( 0 [,) +oo ) A. y e. ( 0 [,) +oo ) ( x x. y ) e. ( 0 [,) +oo )
22		eqid	\|- ( mulGrp ` CCfld ) = ( mulGrp ` CCfld )
23	22	ringmgp	\|- ( CCfld e. Ring -> ( mulGrp ` CCfld ) e. Mnd )
24		cnfldbas	\|- CC = ( Base ` CCfld )
25	22 24	mgpbas	\|- CC = ( Base ` ( mulGrp ` CCfld ) )
26		cnfld1	\|- 1 = ( 1r ` CCfld )
27	22 26	ringidval	\|- 1 = ( 0g ` ( mulGrp ` CCfld ) )
28		cnfldmul	\|- x. = ( .r ` CCfld )
29	22 28	mgpplusg	\|- x. = ( +g ` ( mulGrp ` CCfld ) )
30	25 27 29	issubm	\|- ( ( mulGrp ` CCfld ) e. Mnd -> ( ( 0 [,) +oo ) e. ( SubMnd ` ( mulGrp ` CCfld ) ) <-> ( ( 0 [,) +oo ) C_ CC /\ 1 e. ( 0 [,) +oo ) /\ A. x e. ( 0 [,) +oo ) A. y e. ( 0 [,) +oo ) ( x x. y ) e. ( 0 [,) +oo ) ) ) )
31	1 23 30	mp2b	\|- ( ( 0 [,) +oo ) e. ( SubMnd ` ( mulGrp ` CCfld ) ) <-> ( ( 0 [,) +oo ) C_ CC /\ 1 e. ( 0 [,) +oo ) /\ A. x e. ( 0 [,) +oo ) A. y e. ( 0 [,) +oo ) ( x x. y ) e. ( 0 [,) +oo ) ) )
32	10 19 21 31	mpbir3an	\|- ( 0 [,) +oo ) e. ( SubMnd ` ( mulGrp ` CCfld ) )
33		eqid	\|- ( ( mulGrp ` CCfld ) \|`s ( 0 [,) +oo ) ) = ( ( mulGrp ` CCfld ) \|`s ( 0 [,) +oo ) )
34	33	submmnd	\|- ( ( 0 [,) +oo ) e. ( SubMnd ` ( mulGrp ` CCfld ) ) -> ( ( mulGrp ` CCfld ) \|`s ( 0 [,) +oo ) ) e. Mnd )
35	32 34	ax-mp	\|- ( ( mulGrp ` CCfld ) \|`s ( 0 [,) +oo ) ) e. Mnd
36		simpll	\|- ( ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) /\ z e. ( 0 [,) +oo ) ) -> x e. ( 0 [,) +oo ) )
37	10 36	sseldi	\|- ( ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) /\ z e. ( 0 [,) +oo ) ) -> x e. CC )
38		simplr	\|- ( ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) /\ z e. ( 0 [,) +oo ) ) -> y e. ( 0 [,) +oo ) )
39	10 38	sseldi	\|- ( ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) /\ z e. ( 0 [,) +oo ) ) -> y e. CC )
40		simpr	\|- ( ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) /\ z e. ( 0 [,) +oo ) ) -> z e. ( 0 [,) +oo ) )
41	10 40	sseldi	\|- ( ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) /\ z e. ( 0 [,) +oo ) ) -> z e. CC )
42	37 39 41	adddid	\|- ( ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) /\ z e. ( 0 [,) +oo ) ) -> ( x x. ( y + z ) ) = ( ( x x. y ) + ( x x. z ) ) )
43	37 39 41	adddird	\|- ( ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) /\ z e. ( 0 [,) +oo ) ) -> ( ( x + y ) x. z ) = ( ( x x. z ) + ( y x. z ) ) )
44	42 43	jca	\|- ( ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) /\ z e. ( 0 [,) +oo ) ) -> ( ( x x. ( y + z ) ) = ( ( x x. y ) + ( x x. z ) ) /\ ( ( x + y ) x. z ) = ( ( x x. z ) + ( y x. z ) ) ) )
45	44	ralrimiva	\|- ( ( x e. ( 0 [,) +oo ) /\ y e. ( 0 [,) +oo ) ) -> A. z e. ( 0 [,) +oo ) ( ( x x. ( y + z ) ) = ( ( x x. y ) + ( x x. z ) ) /\ ( ( x + y ) x. z ) = ( ( x x. z ) + ( y x. z ) ) ) )
46	45	ralrimiva	\|- ( x e. ( 0 [,) +oo ) -> A. y e. ( 0 [,) +oo ) A. z e. ( 0 [,) +oo ) ( ( x x. ( y + z ) ) = ( ( x x. y ) + ( x x. z ) ) /\ ( ( x + y ) x. z ) = ( ( x x. z ) + ( y x. z ) ) ) )
47	10	sseli	\|- ( x e. ( 0 [,) +oo ) -> x e. CC )
48	47	mul02d	\|- ( x e. ( 0 [,) +oo ) -> ( 0 x. x ) = 0 )
49	47	mul01d	\|- ( x e. ( 0 [,) +oo ) -> ( x x. 0 ) = 0 )
50	46 48 49	jca32	\|- ( x e. ( 0 [,) +oo ) -> ( A. y e. ( 0 [,) +oo ) A. z e. ( 0 [,) +oo ) ( ( x x. ( y + z ) ) = ( ( x x. y ) + ( x x. z ) ) /\ ( ( x + y ) x. z ) = ( ( x x. z ) + ( y x. z ) ) ) /\ ( ( 0 x. x ) = 0 /\ ( x x. 0 ) = 0 ) ) )
51	50	rgen	\|- A. x e. ( 0 [,) +oo ) ( A. y e. ( 0 [,) +oo ) A. z e. ( 0 [,) +oo ) ( ( x x. ( y + z ) ) = ( ( x x. y ) + ( x x. z ) ) /\ ( ( x + y ) x. z ) = ( ( x x. z ) + ( y x. z ) ) ) /\ ( ( 0 x. x ) = 0 /\ ( x x. 0 ) = 0 ) )
52	5 24	ressbas2	\|- ( ( 0 [,) +oo ) C_ CC -> ( 0 [,) +oo ) = ( Base ` ( CCfld \|`s ( 0 [,) +oo ) ) ) )
53	10 52	ax-mp	\|- ( 0 [,) +oo ) = ( Base ` ( CCfld \|`s ( 0 [,) +oo ) ) )
54		cnfldex	\|- CCfld e. _V
55		ovex	\|- ( 0 [,) +oo ) e. _V
56	5 22	mgpress	\|- ( ( CCfld e. _V /\ ( 0 [,) +oo ) e. _V ) -> ( ( mulGrp ` CCfld ) \|`s ( 0 [,) +oo ) ) = ( mulGrp ` ( CCfld \|`s ( 0 [,) +oo ) ) ) )
57	54 55 56	mp2an	\|- ( ( mulGrp ` CCfld ) \|`s ( 0 [,) +oo ) ) = ( mulGrp ` ( CCfld \|`s ( 0 [,) +oo ) ) )
58		cnfldadd	\|- + = ( +g ` CCfld )
59	5 58	ressplusg	\|- ( ( 0 [,) +oo ) e. _V -> + = ( +g ` ( CCfld \|`s ( 0 [,) +oo ) ) ) )
60	55 59	ax-mp	\|- + = ( +g ` ( CCfld \|`s ( 0 [,) +oo ) ) )
61	5 28	ressmulr	\|- ( ( 0 [,) +oo ) e. _V -> x. = ( .r ` ( CCfld \|`s ( 0 [,) +oo ) ) ) )
62	55 61	ax-mp	\|- x. = ( .r ` ( CCfld \|`s ( 0 [,) +oo ) ) )
63		ringmnd	\|- ( CCfld e. Ring -> CCfld e. Mnd )
64	1 63	ax-mp	\|- CCfld e. Mnd
65		0e0icopnf	\|- 0 e. ( 0 [,) +oo )
66		cnfld0	\|- 0 = ( 0g ` CCfld )
67	5 24 66	ress0g	\|- ( ( CCfld e. Mnd /\ 0 e. ( 0 [,) +oo ) /\ ( 0 [,) +oo ) C_ CC ) -> 0 = ( 0g ` ( CCfld \|`s ( 0 [,) +oo ) ) ) )
68	64 65 10 67	mp3an	\|- 0 = ( 0g ` ( CCfld \|`s ( 0 [,) +oo ) ) )
69	53 57 60 62 68	issrg	\|- ( ( CCfld \|`s ( 0 [,) +oo ) ) e. SRing <-> ( ( CCfld \|`s ( 0 [,) +oo ) ) e. CMnd /\ ( ( mulGrp ` CCfld ) \|`s ( 0 [,) +oo ) ) e. Mnd /\ A. x e. ( 0 [,) +oo ) ( A. y e. ( 0 [,) +oo ) A. z e. ( 0 [,) +oo ) ( ( x x. ( y + z ) ) = ( ( x x. y ) + ( x x. z ) ) /\ ( ( x + y ) x. z ) = ( ( x x. z ) + ( y x. z ) ) ) /\ ( ( 0 x. x ) = 0 /\ ( x x. 0 ) = 0 ) ) ) )
70	7 35 51 69	mpbir3an	\|- ( CCfld \|`s ( 0 [,) +oo ) ) e. SRing

Metamath Proof Explorer

Theorem rge0srg

Proof