axdistr - Metamath Proof Explorer

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Theorem axdistr 5251

Description: Distributive law for complex numbers. Axiom 13 of 25 for real and complex numbers, derived from ZF set theory.

**Assertion**
Ref	Expression
axdistr	⊢ ((A ∈ ℂ ⋀ B ∈ ℂ ⋀ C ∈ ℂ) → (A · (B + C)) = ((A · B) + (A · C)))

**Proof of Theorem axdistr**
Step	Hyp	Ref	Expression
1		dfcnqs 5234	. 2 ⊢ ℂ = ((R × R) / ^◡E)
2		addcnsrec 5235	. 2 ⊢ (((z ∈ R ⋀ w ∈ R) ⋀ (v ∈ R ⋀ u ∈ R)) → ([⟨z, w⟩]^◡E + [⟨v, u⟩]^◡E) = [⟨(z +_R v), (w +_R u)⟩]^◡E)
3		mulcnsrec 5236	. 2 ⊢ (((x ∈ R ⋀ y ∈ R) ⋀ ((z +_R v) ∈ R ⋀ (w +_R u) ∈ R)) → ([⟨x, y⟩]^◡E · [⟨(z +_R v), (w +_R u)⟩]^◡E) = [⟨((x ·_R (z +_R v)) +_R (-1_R ·_R (y ·_R (w +_R u)))), ((y ·_R (z +_R v)) +_R (x ·_R (w +_R u)))⟩]^◡E)
4		mulcnsrec 5236	. 2 ⊢ (((x ∈ R ⋀ y ∈ R) ⋀ (z ∈ R ⋀ w ∈ R)) → ([⟨x, y⟩]^◡E · [⟨z, w⟩]^◡E) = [⟨((x ·_R z) +_R (-1_R ·_R (y ·_R w))), ((y ·_R z) +_R (x ·_R w))⟩]^◡E)
5		mulcnsrec 5236	. 2 ⊢ (((x ∈ R ⋀ y ∈ R) ⋀ (v ∈ R ⋀ u ∈ R)) → ([⟨x, y⟩]^◡E · [⟨v, u⟩]^◡E) = [⟨((x ·_R v) +_R (-1_R ·_R (y ·_R u))), ((y ·_R v) +_R (x ·_R u))⟩]^◡E)
6		addcnsrec 5235	. 2 ⊢ (((((x ·_R z) +_R (-1_R ·_R (y ·_R w))) ∈ R ⋀ ((y ·_R z) +_R (x ·_R w)) ∈ R) ⋀ (((x ·_R v) +_R (-1_R ·_R (y ·_R u))) ∈ R ⋀ ((y ·_R v) +_R (x ·_R u)) ∈ R)) → ([⟨((x ·_R z) +_R (-1_R ·_R (y ·_R w))), ((y ·_R z) +_R (x ·_R w))⟩]^◡E + [⟨((x ·_R v) +_R (-1_R ·_R (y ·_R u))), ((y ·_R v) +_R (x ·_R u))⟩]^◡E) = [⟨(((x ·_R z) +_R (-1_R ·_R (y ·_R w))) +_R ((x ·_R v) +_R (-1_R ·_R (y ·_R u)))), (((y ·_R z) +_R (x ·_R w)) +_R ((y ·_R v) +_R (x ·_R u)))⟩]^◡E)
7		addclsr 5164	. . . 4 ⊢ ((z ∈ R ⋀ v ∈ R) → (z +_R v) ∈ R)
8		addclsr 5164	. . . 4 ⊢ ((w ∈ R ⋀ u ∈ R) → (w +_R u) ∈ R)
9	7, 8	anim12i 333	. . 3 ⊢ (((z ∈ R ⋀ v ∈ R) ⋀ (w ∈ R ⋀ u ∈ R)) → ((z +_R v) ∈ R ⋀ (w +_R u) ∈ R))
10	9	an4s 507	. 2 ⊢ (((z ∈ R ⋀ w ∈ R) ⋀ (v ∈ R ⋀ u ∈ R)) → ((z +_R v) ∈ R ⋀ (w +_R u) ∈ R))
11		addclsr 5164	. . . . 5 ⊢ (((x ·_R z) ∈ R ⋀ (-1_R ·_R (y ·_R w)) ∈ R) → ((x ·_R z) +_R (-1_R ·_R (y ·_R w))) ∈ R)
12		mulclsr 5165	. . . . 5 ⊢ ((x ∈ R ⋀ z ∈ R) → (x ·_R z) ∈ R)
13		mulclsr 5165	. . . . . 6 ⊢ ((y ∈ R ⋀ w ∈ R) → (y ·_R w) ∈ R)
14		m1r 5163	. . . . . . 7 ⊢ -1_R ∈ R
15		mulclsr 5165	. . . . . . 7 ⊢ ((-1_R ∈ R ⋀ (y ·_R w) ∈ R) → (-1_R ·_R (y ·_R w)) ∈ R)
16	14, 15	mpan 693	. . . . . 6 ⊢ ((y ·_R w) ∈ R → (-1_R ·_R (y ·_R w)) ∈ R)
17	13, 16	syl 10	. . . . 5 ⊢ ((y ∈ R ⋀ w ∈ R) → (-1_R ·_R (y ·_R w)) ∈ R)
18	11, 12, 17	syl2an 454	. . . 4 ⊢ (((x ∈ R ⋀ z ∈ R) ⋀ (y ∈ R ⋀ w ∈ R)) → ((x ·_R z) +_R (-1_R ·_R (y ·_R w))) ∈ R)
19	18	an4s 507	. . 3 ⊢ (((x ∈ R ⋀ y ∈ R) ⋀ (z ∈ R ⋀ w ∈ R)) → ((x ·_R z) +_R (-1_R ·_R (y ·_R w))) ∈ R)
20		addclsr 5164	. . . . . 6 ⊢ (((y ·_R z) ∈ R ⋀ (x ·_R w) ∈ R) → ((y ·_R z) +_R (x ·_R w)) ∈ R)
21		mulclsr 5165	. . . . . 6 ⊢ ((y ∈ R ⋀ z ∈ R) → (y ·_R z) ∈ R)
22		mulclsr 5165	. . . . . 6 ⊢ ((x ∈ R ⋀ w ∈ R) → (x ·_R w) ∈ R)
23	20, 21, 22	syl2an 454	. . . . 5 ⊢ (((y ∈ R ⋀ z ∈ R) ⋀ (x ∈ R ⋀ w ∈ R)) → ((y ·_R z) +_R (x ·_R w)) ∈ R)
24	23	ancoms 436	. . . 4 ⊢ (((x ∈ R ⋀ w ∈ R) ⋀ (y ∈ R ⋀ z ∈ R)) → ((y ·_R z) +_R (x ·_R w)) ∈ R)
25	24	an42s 508	. . 3 ⊢ (((x ∈ R ⋀ y ∈ R) ⋀ (z ∈ R ⋀ w ∈ R)) → ((y ·_R z) +_R (x ·_R w)) ∈ R)
26	19, 25	jca 288	. 2 ⊢ (((x ∈ R ⋀ y ∈ R) ⋀ (z ∈ R ⋀ w ∈ R)) → (((x ·_R z) +_R (-1_R ·_R (y ·_R w))) ∈ R ⋀ ((y ·_R z) +_R (x ·_R w)) ∈ R))
27		addclsr 5164	. . . . 5 ⊢ (((x ·_R v) ∈ R ⋀ (-1_R ·_R (y ·_R u)) ∈ R) → ((x ·_R v) +_R (-1_R ·_R (y ·_R u))) ∈ R)
28		mulclsr 5165	. . . . 5 ⊢ ((x ∈ R ⋀ v ∈ R) → (x ·_R v) ∈ R)
29		mulclsr 5165	. . . . . 6 ⊢ ((y ∈ R ⋀ u ∈ R) → (y ·_R u) ∈ R)
30		mulclsr 5165	. . . . . . 7 ⊢ ((-1_R ∈ R ⋀ (y ·_R u) ∈ R) → (-1_R ·_R (y ·_R u)) ∈ R)
31	14, 30	mpan 693	. . . . . 6 ⊢ ((y ·_R u) ∈ R → (-1_R ·_R (y ·_R u)) ∈ R)
32	29, 31	syl 10	. . . . 5 ⊢ ((y ∈ R ⋀ u ∈ R) → (-1_R ·_R (y ·_R u)) ∈ R)
33	27, 28, 32	syl2an 454	. . . 4 ⊢ (((x ∈ R ⋀ v ∈ R) ⋀ (y ∈ R ⋀ u ∈ R)) → ((x ·_R v) +_R (-1_R ·_R (y ·_R u))) ∈ R)
34	33	an4s 507	. . 3 ⊢ (((x ∈ R ⋀ y ∈ R) ⋀ (v ∈ R ⋀ u ∈ R)) → ((x ·_R v) +_R (-1_R ·_R (y ·_R u))) ∈ R)
35		addclsr 5164	. . . . . 6 ⊢ (((y ·_R v) ∈ R ⋀ (x ·_R u) ∈ R) → ((y ·_R v) +_R (x ·_R u)) ∈ R)
36		mulclsr 5165	. . . . . 6 ⊢ ((y ∈ R ⋀ v ∈ R) → (y ·_R v) ∈ R)
37		mulclsr 5165	. . . . . 6 ⊢ ((x ∈ R ⋀ u ∈ R) → (x ·_R u) ∈ R)
38	35, 36, 37	syl2an 454	. . . . 5 ⊢ (((y ∈ R ⋀ v ∈ R) ⋀ (x ∈ R ⋀ u ∈ R)) → ((y ·_R v) +_R (x ·_R u)) ∈ R)
39	38	ancoms 436	. . . 4 ⊢ (((x ∈ R ⋀ u ∈ R) ⋀ (y ∈ R ⋀ v ∈ R)) → ((y ·_R v) +_R (x ·_R u)) ∈ R)
40	39	an42s 508	. . 3 ⊢ (((x ∈ R ⋀ y ∈ R) ⋀ (v ∈ R ⋀ u ∈ R)) → ((y ·_R v) +_R (x ·_R u)) ∈ R)
41	34, 40	jca 288	. 2 ⊢ (((x ∈ R ⋀ y ∈ R) ⋀ (v ∈ R ⋀ u ∈ R)) → (((x ·_R v) +_R (-1_R ·_R (y ·_R u))) ∈ R ⋀ ((y ·_R v) +_R (x ·_R u)) ∈ R))
42		visset 1804	. . . . 5 ⊢ z ∈ V
43		visset 1804	. . . . 5 ⊢ v ∈ V
44	42, 43	distrsr 5172	. . . 4 ⊢ (x ·_R (z +_R v)) = ((x ·_R z) +_R (x ·_R v))
45		visset 1804	. . . . . . 7 ⊢ w ∈ V
46		visset 1804	. . . . . . 7 ⊢ u ∈ V
47	45, 46	distrsr 5172	. . . . . 6 ⊢ (y ·_R (w +_R u)) = ((y ·_R w) +_R (y ·_R u))
48	47	opreq2i 3957	. . . . 5 ⊢ (-1_R ·_R (y ·_R (w +_R u))) = (-1_R ·_R ((y ·_R w) +_R (y ·_R u)))
49		oprex 3968	. . . . . 6 ⊢ (y ·_R w) ∈ V
50		oprex 3968	. . . . . 6 ⊢ (y ·_R u) ∈ V
51	49, 50	distrsr 5172	. . . . 5 ⊢ (-1_R ·_R ((y ·_R w) +_R (y ·_R u))) = ((-1_R ·_R (y ·_R w)) +_R (-1_R ·_R (y ·_R u)))
52	48, 51	eqtr 1487	. . . 4 ⊢ (-1_R ·_R (y ·_R (w +_R u))) = ((-1_R ·_R (y ·_R w)) +_R (-1_R ·_R (y ·_R u)))
53	44, 52	opreq12i 3958	. . 3 ⊢ ((x ·_R (z +_R v)) +_R (-1_R ·_R (y ·_R (w +_R u)))) = (((x ·_R z) +_R (x ·_R v)) +_R ((-1_R ·_R (y ·_R w)) +_R (-1_R ·_R (y ·_R u))))
54		oprex 3968	. . . 4 ⊢ (x ·_R z) ∈ V
55		oprex 3968	. . . 4 ⊢ (x ·_R v) ∈ V
56		oprex 3968	. . . 4 ⊢ (-1_R ·_R (y ·_R w)) ∈ V
57		visset 1804	. . . . 5 ⊢ f ∈ V
58		visset 1804	. . . . 5 ⊢ g ∈ V
59	57, 58	addcomsr 5168	. . . 4 ⊢ (f +_R g) = (g +_R f)
60		visset 1804	. . . . 5 ⊢ h ∈ V
61	58, 60	addasssr 5169	. . . 4 ⊢ ((f +_R g) +_R h) = (f +_R (g +_R h))
62		oprex 3968	. . . 4 ⊢ (-1_R ·_R (y ·_R u)) ∈ V
63	54, 55, 56, 59, 61, 62	caopr4 4050	. . 3 ⊢ (((x ·_R z) +_R (x ·_R v)) +_R ((-1_R ·_R (y ·_R w)) +_R (-1_R ·_R (y ·_R u)))) = (((x ·_R z) +_R (-1_R ·_R (y ·_R w))) +_R ((x ·_R v) +_R (-1_R ·_R (y ·_R u))))
64	53, 63	eqtr 1487	. 2 ⊢ ((x ·_R (z +_R v)) +_R (-1_R ·_R (y ·_R (w +_R u)))) = (((x ·_R z) +_R (-1_R ·_R (y ·_R w))) +_R ((x ·_R v) +_R (-1_R ·_R (y ·_R u))))
65	42, 43	distrsr 5172	. . . 4 ⊢ (y ·_R (z +_R v)) = ((y ·_R z) +_R (y ·_R v))
66	45, 46	distrsr 5172	. . . 4 ⊢ (x ·_R (w +_R u)) = ((x ·_R w) +_R (x ·_R u))
67	65, 66	opreq12i 3958	. . 3 ⊢ ((y ·_R (z +_R v)) +_R (x ·_R (w +_R u))) = (((y ·_R z) +_R (y ·_R v)) +_R ((x ·_R w) +_R (x ·_R u)))
68		oprex 3968	. . . 4 ⊢ (y ·_R z) ∈ V
69		oprex 3968	. . . 4 ⊢ (y ·_R v) ∈ V
70		oprex 3968	. . . 4 ⊢ (x ·_R w) ∈ V
71		oprex 3968	. . . 4 ⊢ (x ·_R u) ∈ V
72	68, 69, 70, 59, 61, 71	caopr4 4050	. . 3 ⊢ (((y ·_R z) +_R (y ·_R v)) +_R ((x ·_R w) +_R (x ·_R u))) = (((y ·_R z) +_R (x ·_R w)) +_R ((y ·_R v) +_R (x ·_R u)))
73	67, 72	eqtr 1487	. 2 ⊢ ((y ·_R (z +_R v)) +_R (x ·_R (w +_R u))) = (((y ·_R z) +_R (x ·_R w)) +_R ((y ·_R v) +_R (x ·_R u)))
74	1, 2, 3, 4, 5, 6, 10, 26, 41, 64, 73	ecoprdi 4305	1 ⊢ ((A ∈ ℂ ⋀ B ∈ ℂ ⋀ C ∈ ℂ) → (A · (B + C)) = ((A · B) + (A · C)))

Colors of variables: wff set class

Syntax hints: → wi 3 ⋀ wa 223 ⋀ w3a 773 = wceq 953 ∈ wcel 955 Ecep 2819 ^◡ccnv 3159 (class class class)co 3948 Rcnr 4965 -1_Rcm1r 4968 +_R cplr 4969 ·_R cmr 4970 ℂcc 5204 + caddc 5209 · cmul 5211

This theorem is referenced by: adddit 5281 adddirt 5291 adddi 5298 cnegext 5320 muladdt 5393 muladd11t 5394 subdit 5399 conjmult 5753 nnmulclt 5889 expmult 6528 bernneq 6583 imret 6710 fsummulc1 6971 binomlem5 7008 efexpt 7314 efi4pt 7377 cos01bndlem3 7413 demoivre 7426 cnring 8099 cnvc 8140 ipasslem2 8422 efgh 8633 shftefif1olem 8661 shftefif1olemOLD 8662 hhph 8966 mslb1 10473

This theorem was proved from axioms: ax-1 4 ax-2 5 ax-3 6 ax-mp 7 ax-7 959 ax-gen 960 ax-8 961 ax-9 962 ax-10 963 ax-11 964 ax-12 965 ax-13 966 ax-14 967 ax-17 968 ax-4 970 ax-5o 972 ax-6o 975 ax-9o 1119 ax-10o 1136 ax-16 1206 ax-11o 1213 ax-ext 1452 ax-rep 2683 ax-sep 2693 ax-nul 2700 ax-pow 2732 ax-pr 2769 ax-un 2857 ax-inf2 4597

This theorem depends on definitions: df-bi 147 df-or 224 df-an 225 df-3or 774 df-3an 775 df-ex 978 df-sb 1168 df-eu 1375 df-mo 1376 df-clab 1457 df-cleq 1462 df-clel 1465 df-ne 1579 df-ral 1641 df-rex 1642 df-reu 1643 df-rab 1644 df-v 1803 df-sbc 1932 df-csb 1992 df-dif 2039 df-un 2040 df-in 2041 df-ss 2043 df-pss 2045 df-nul 2271 df-if 2352 df-pw 2392 df-sn 2402 df-pr 2403 df-tp 2405 df-op 2406 df-uni 2494 df-int 2524 df-iun 2558 df-br 2610 df-opab 2657 df-tr 2671 df-eprel 2821 df-id 2824 df-po 2831 df-so 2841 df-fr 2907 df-we 2924 df-ord 2941 df-on 2942 df-lim 2943 df-suc 2944 df-om 3122 df-xp 3174 df-rel 3175 df-cnv 3176 df-co 3177 df-dm 3178 df-rn 3179 df-res 3180 df-ima 3181 df-fun 3182 df-fn 3183 df-f 3184 df-fv 3188 df-rdg 3917 df-opr 3950 df-oprab 3951 df-1st 4063 df-2nd 4064 df-1o 4117 df-oadd 4119 df-omul 4120 df-er 4245 df-ec 4247 df-qs 4250 df-ni 4972 df-pli 4973 df-mi 4974 df-lti 4975 df-plpq 5007 df-mpq 5008 df-enq 5009 df-nq 5010 df-plq 5011 df-mq 5012 df-rq 5013 df-ltq 5014 df-1q 5015 df-np 5058 df-1p 5059 df-plp 5060 df-mp 5061 df-ltp 5062 df-plpr 5136 df-mpr 5137 df-enr 5138 df-nr 5139 df-plr 5140 df-mr 5141 df-m1r 5145 df-c 5212 df-plus 5217 df-mul 5218