rngnegr

Description: Negation in a ring is the same as right multiplication by -1. ( rngonegmn1r analog.) (Contributed by Jeff Madsen, 19-Jun-2010) (Revised by Mario Carneiro, 2-Jul-2014)

	Ref	Expression
Hypotheses	ringnegl.b	\|- B = ( Base ` R )
	ringnegl.t	\|- .x. = ( .r ` R )
	ringnegl.u	\|- .1. = ( 1r ` R )
	ringnegl.n	\|- N = ( invg ` R )
	ringnegl.r	\|- ( ph -> R e. Ring )
	ringnegl.x	\|- ( ph -> X e. B )
Assertion	rngnegr	\|- ( ph -> ( X .x. ( N ` .1. ) ) = ( N ` X ) )

Proof

Step	Hyp	Ref	Expression
1		ringnegl.b	\|- B = ( Base ` R )
2		ringnegl.t	\|- .x. = ( .r ` R )
3		ringnegl.u	\|- .1. = ( 1r ` R )
4		ringnegl.n	\|- N = ( invg ` R )
5		ringnegl.r	\|- ( ph -> R e. Ring )
6		ringnegl.x	\|- ( ph -> X e. B )
7		ringgrp	\|- ( R e. Ring -> R e. Grp )
8	5 7	syl	\|- ( ph -> R e. Grp )
9	1 3	ringidcl	\|- ( R e. Ring -> .1. e. B )
10	5 9	syl	\|- ( ph -> .1. e. B )
11	1 4	grpinvcl	\|- ( ( R e. Grp /\ .1. e. B ) -> ( N ` .1. ) e. B )
12	8 10 11	syl2anc	\|- ( ph -> ( N ` .1. ) e. B )
13		eqid	\|- ( +g ` R ) = ( +g ` R )
14	1 13 2	ringdi	\|- ( ( R e. Ring /\ ( X e. B /\ ( N ` .1. ) e. B /\ .1. e. B ) ) -> ( X .x. ( ( N ` .1. ) ( +g ` R ) .1. ) ) = ( ( X .x. ( N ` .1. ) ) ( +g ` R ) ( X .x. .1. ) ) )
15	5 6 12 10 14	syl13anc	\|- ( ph -> ( X .x. ( ( N ` .1. ) ( +g ` R ) .1. ) ) = ( ( X .x. ( N ` .1. ) ) ( +g ` R ) ( X .x. .1. ) ) )
16		eqid	\|- ( 0g ` R ) = ( 0g ` R )
17	1 13 16 4	grplinv	\|- ( ( R e. Grp /\ .1. e. B ) -> ( ( N ` .1. ) ( +g ` R ) .1. ) = ( 0g ` R ) )
18	8 10 17	syl2anc	\|- ( ph -> ( ( N ` .1. ) ( +g ` R ) .1. ) = ( 0g ` R ) )
19	18	oveq2d	\|- ( ph -> ( X .x. ( ( N ` .1. ) ( +g ` R ) .1. ) ) = ( X .x. ( 0g ` R ) ) )
20	1 2 16	ringrz	\|- ( ( R e. Ring /\ X e. B ) -> ( X .x. ( 0g ` R ) ) = ( 0g ` R ) )
21	5 6 20	syl2anc	\|- ( ph -> ( X .x. ( 0g ` R ) ) = ( 0g ` R ) )
22	19 21	eqtrd	\|- ( ph -> ( X .x. ( ( N ` .1. ) ( +g ` R ) .1. ) ) = ( 0g ` R ) )
23	1 2 3	ringridm	\|- ( ( R e. Ring /\ X e. B ) -> ( X .x. .1. ) = X )
24	5 6 23	syl2anc	\|- ( ph -> ( X .x. .1. ) = X )
25	24	oveq2d	\|- ( ph -> ( ( X .x. ( N ` .1. ) ) ( +g ` R ) ( X .x. .1. ) ) = ( ( X .x. ( N ` .1. ) ) ( +g ` R ) X ) )
26	15 22 25	3eqtr3rd	\|- ( ph -> ( ( X .x. ( N ` .1. ) ) ( +g ` R ) X ) = ( 0g ` R ) )
27	1 2	ringcl	\|- ( ( R e. Ring /\ X e. B /\ ( N ` .1. ) e. B ) -> ( X .x. ( N ` .1. ) ) e. B )
28	5 6 12 27	syl3anc	\|- ( ph -> ( X .x. ( N ` .1. ) ) e. B )
29	1 13 16 4	grpinvid2	\|- ( ( R e. Grp /\ X e. B /\ ( X .x. ( N ` .1. ) ) e. B ) -> ( ( N ` X ) = ( X .x. ( N ` .1. ) ) <-> ( ( X .x. ( N ` .1. ) ) ( +g ` R ) X ) = ( 0g ` R ) ) )
30	8 6 28 29	syl3anc	\|- ( ph -> ( ( N ` X ) = ( X .x. ( N ` .1. ) ) <-> ( ( X .x. ( N ` .1. ) ) ( +g ` R ) X ) = ( 0g ` R ) ) )
31	26 30	mpbird	\|- ( ph -> ( N ` X ) = ( X .x. ( N ` .1. ) ) )
32	31	eqcomd	\|- ( ph -> ( X .x. ( N ` .1. ) ) = ( N ` X ) )

Metamath Proof Explorer

Theorem rngnegr

Proof