Theorem grpnnncan2 8089

Description: Group theory analog of nnncan2t 5480.

Hypotheses

Ref	Expression
grpdivf.1	|- X = ran G
grpdivf.3	|- D = ( /g ` G)

Assertion

Ref	Expression
grpnnncan2	|- ((G e. Grp /\ (A e. X /\ B e. X /\ C e. X)) -> ((ADC)D(BDC)) = (ADB))

Proof of Theorem grpnnncan2

Step	Hyp	Ref	Expression
1		grpdivf.1	. . . . 5 |- X = ran G
2		eqid 1478	. . . . 5 |- (inv` G) = (inv` G)
3		grpdivf.3	. . . . 5 |- D = ( /g ` G)
4	1, 2, 3	grpdivval 8078	. . . 4 |- ((G e. Grp /\ A e. X /\ C e. X) -> (ADC) = (AG((inv` G)` C)))
5	4	3adant3r2 845	. . 3 |- ((G e. Grp /\ (A e. X /\ B e. X /\ C e. X)) -> (ADC) = (AG((inv` G)` C)))
6	1, 2, 3	grpdivval 8078	. . . 4 |- ((G e. Grp /\ B e. X /\ C e. X) -> (BDC) = (BG((inv` G)` C)))
7	6	3adant3r1 844	. . 3 |- ((G e. Grp /\ (A e. X /\ B e. X /\ C e. X)) -> (BDC) = (BG((inv` G)` C)))
8	5, 7	opreq12d 3984	. 2 |- ((G e. Grp /\ (A e. X /\ B e. X /\ C e. X)) -> ((ADC)D(BDC)) = ((AG((inv` G)` C))D(BG((inv` G)` C))))
9		idd 61	. . . . 5 |- (G e. Grp -> (A e. X -> A e. X))
10		idd 61	. . . . 5 |- (G e. Grp -> (B e. X -> B e. X))
11	1, 2	grpinvcl 8064	. . . . . 6 |- ((G e. Grp /\ C e. X) -> ((inv` G)` C) e. X)
12	11	ex 373	. . . . 5 |- (G e. Grp -> (C e. X -> ((inv` G)` C) e. X))
13	9, 10, 12	3anim123d 902	. . . 4 |- (G e. Grp -> ((A e. X /\ B e. X /\ C e. X) -> (A e. X /\ B e. X /\ ((inv` G)` C) e. X)))
14	13	imp 350	. . 3 |- ((G e. Grp /\ (A e. X /\ B e. X /\ C e. X)) -> (A e. X /\ B e. X /\ ((inv` G)` C) e. X))
15	1, 3	grppnpcan2 8088	. . 3 |- ((G e. Grp /\ (A e. X /\ B e. X /\ ((inv` G)` C) e. X)) -> ((AG((inv` G)` C))D(BG((inv` G)` C))) = (ADB))
16	14, 15	syldan 469	. 2 |- ((G e. Grp /\ (A e. X /\ B e. X /\ C e. X)) -> ((AG((inv` G)` C))D(BG((inv` G)` C))) = (ADB))
17	8, 16	eqtrd 1510	1 |- ((G e. Grp /\ (A e. X /\ B e. X /\ C e. X)) -> ((ADC)D(BDC)) = (ADB))

Syntax hints:   -> wi 3   /\ wa 223   /\ w3a 777   = wceq 958   e. wcel 960  ran crn 3177  ` cfv 3188  (class class class)co 3969  Grpcgr 8030  invcgn 8032   /g cgs 8033

This theorem is referenced by:  nvnnncan2 8265

This theorem was proved from axioms:  ax-1 4  ax-2 5  ax-3 6  ax-mp 7  ax-7 964  ax-gen 965  ax-8 966  ax-9 967  ax-10 968  ax-11 969  ax-12 970  ax-13 971  ax-14 972  ax-17 973  ax-4 975  ax-5o 977  ax-6o 980  ax-9o 1125  ax-10o 1142  ax-16 1212  ax-11o 1220  ax-ext 1462  ax-rep 2698  ax-sep 2708  ax-pow 2748  ax-pr 2785  ax-un 2872

This theorem depends on definitions:  df-bi 147  df-or 224  df-an 225  df-3an 779  df-ex 983  df-sb 1174  df-eu 1384  df-mo 1385  df-clab 1467  df-cleq 1472  df-clel 1475  df-ne 1590  df-ral 1652  df-rex 1653  df-reu 1654  df-rab 1655  df-v 1815  df-sbc 1945  df-csb 2005  df-dif 2052  df-un 2053  df-in 2054  df-ss 2056  df-nul 2284  df-pw 2406  df-sn 2416  df-pr 2417  df-op 2420  df-uni 2508  df-br 2625  df-opab 2672  df-id 2841  df-xp 3190  df-rel 3191  df-cnv 3192  df-co 3193  df-dm 3194  df-rn 3195  df-res 3196  df-ima 3197  df-fun 3198  df-fn 3199  df-f 3200  df-fo 3202  df-fv 3204  df-opr 3971  df-oprab 3972  df-grp 8034  df-gid 8035  df-ginv 8036  df-gdiv 8037

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