mulgnegnn

Description: Group multiple (exponentiation) operation at a negative integer. (Contributed by Mario Carneiro, 11-Dec-2014)

	Ref	Expression
Hypotheses	mulg1.b	\|- B = ( Base ` G )
	mulg1.m	\|- .x. = ( .g ` G )
	mulgnegnn.i	\|- I = ( invg ` G )
Assertion	mulgnegnn	\|- ( ( N e. NN /\ X e. B ) -> ( -u N .x. X ) = ( I ` ( N .x. X ) ) )

Proof

Step	Hyp	Ref	Expression
1		mulg1.b	\|- B = ( Base ` G )
2		mulg1.m	\|- .x. = ( .g ` G )
3		mulgnegnn.i	\|- I = ( invg ` G )
4		nncn	\|- ( N e. NN -> N e. CC )
5	4	negnegd	\|- ( N e. NN -> -u -u N = N )
6	5	adantr	\|- ( ( N e. NN /\ X e. B ) -> -u -u N = N )
7	6	fveq2d	\|- ( ( N e. NN /\ X e. B ) -> ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) = ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` N ) )
8	7	fveq2d	\|- ( ( N e. NN /\ X e. B ) -> ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) = ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` N ) ) )
9		nnnegz	\|- ( N e. NN -> -u N e. ZZ )
10		eqid	\|- ( +g ` G ) = ( +g ` G )
11		eqid	\|- ( 0g ` G ) = ( 0g ` G )
12		eqid	\|- seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) = seq 1 ( ( +g ` G ) , ( NN X. { X } ) )
13	1 10 11 3 2 12	mulgval	\|- ( ( -u N e. ZZ /\ X e. B ) -> ( -u N .x. X ) = if ( -u N = 0 , ( 0g ` G ) , if ( 0 < -u N , ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u N ) , ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) ) ) )
14	9 13	sylan	\|- ( ( N e. NN /\ X e. B ) -> ( -u N .x. X ) = if ( -u N = 0 , ( 0g ` G ) , if ( 0 < -u N , ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u N ) , ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) ) ) )
15		nnne0	\|- ( N e. NN -> N =/= 0 )
16		negeq0	\|- ( N e. CC -> ( N = 0 <-> -u N = 0 ) )
17	16	necon3abid	\|- ( N e. CC -> ( N =/= 0 <-> -. -u N = 0 ) )
18	4 17	syl	\|- ( N e. NN -> ( N =/= 0 <-> -. -u N = 0 ) )
19	15 18	mpbid	\|- ( N e. NN -> -. -u N = 0 )
20	19	iffalsed	\|- ( N e. NN -> if ( -u N = 0 , ( 0g ` G ) , if ( 0 < -u N , ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u N ) , ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) ) ) = if ( 0 < -u N , ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u N ) , ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) ) )
21		nnre	\|- ( N e. NN -> N e. RR )
22	21	renegcld	\|- ( N e. NN -> -u N e. RR )
23		nngt0	\|- ( N e. NN -> 0 < N )
24	21	lt0neg2d	\|- ( N e. NN -> ( 0 < N <-> -u N < 0 ) )
25	23 24	mpbid	\|- ( N e. NN -> -u N < 0 )
26		0re	\|- 0 e. RR
27		ltnsym	\|- ( ( -u N e. RR /\ 0 e. RR ) -> ( -u N < 0 -> -. 0 < -u N ) )
28	26 27	mpan2	\|- ( -u N e. RR -> ( -u N < 0 -> -. 0 < -u N ) )
29	22 25 28	sylc	\|- ( N e. NN -> -. 0 < -u N )
30	29	iffalsed	\|- ( N e. NN -> if ( 0 < -u N , ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u N ) , ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) ) = ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) )
31	20 30	eqtrd	\|- ( N e. NN -> if ( -u N = 0 , ( 0g ` G ) , if ( 0 < -u N , ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u N ) , ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) ) ) = ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) )
32	31	adantr	\|- ( ( N e. NN /\ X e. B ) -> if ( -u N = 0 , ( 0g ` G ) , if ( 0 < -u N , ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u N ) , ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) ) ) = ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) )
33	14 32	eqtrd	\|- ( ( N e. NN /\ X e. B ) -> ( -u N .x. X ) = ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` -u -u N ) ) )
34	1 10 2 12	mulgnn	\|- ( ( N e. NN /\ X e. B ) -> ( N .x. X ) = ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` N ) )
35	34	fveq2d	\|- ( ( N e. NN /\ X e. B ) -> ( I ` ( N .x. X ) ) = ( I ` ( seq 1 ( ( +g ` G ) , ( NN X. { X } ) ) ` N ) ) )
36	8 33 35	3eqtr4d	\|- ( ( N e. NN /\ X e. B ) -> ( -u N .x. X ) = ( I ` ( N .x. X ) ) )

Metamath Proof Explorer

Theorem mulgnegnn

Proof