tendolinv

Description: Left multiplicative inverse for endomorphism. (Contributed by NM, 10-Apr-2014) (Revised by Mario Carneiro, 23-Jun-2014)

	Ref	Expression
Hypotheses	tendoinv.b	\|- B = ( Base ` K )
	tendoinv.h	\|- H = ( LHyp ` K )
	tendoinv.t	\|- T = ( ( LTrn ` K ) ` W )
	tendoinv.e	\|- E = ( ( TEndo ` K ) ` W )
	tendoinv.o	\|- O = ( h e. T \|-> ( _I \|` B ) )
	tendoinv.u	\|- U = ( ( DVecH ` K ) ` W )
	tendoinv.f	\|- F = ( Scalar ` U )
	tendoinv.n	\|- N = ( invr ` F )
Assertion	tendolinv	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( ( N ` S ) o. S ) = ( _I \|` T ) )

Proof

Step	Hyp	Ref	Expression
1		tendoinv.b	\|- B = ( Base ` K )
2		tendoinv.h	\|- H = ( LHyp ` K )
3		tendoinv.t	\|- T = ( ( LTrn ` K ) ` W )
4		tendoinv.e	\|- E = ( ( TEndo ` K ) ` W )
5		tendoinv.o	\|- O = ( h e. T \|-> ( _I \|` B ) )
6		tendoinv.u	\|- U = ( ( DVecH ` K ) ` W )
7		tendoinv.f	\|- F = ( Scalar ` U )
8		tendoinv.n	\|- N = ( invr ` F )
9		simp1	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( K e. HL /\ W e. H ) )
10		eqid	\|- ( ( EDRing ` K ) ` W ) = ( ( EDRing ` K ) ` W )
11	2 10 6 7	dvhsca	\|- ( ( K e. HL /\ W e. H ) -> F = ( ( EDRing ` K ) ` W ) )
12	9 11	syl	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> F = ( ( EDRing ` K ) ` W ) )
13	2 10	erngdv	\|- ( ( K e. HL /\ W e. H ) -> ( ( EDRing ` K ) ` W ) e. DivRing )
14	9 13	syl	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( ( EDRing ` K ) ` W ) e. DivRing )
15	12 14	eqeltrd	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> F e. DivRing )
16		simp2	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> S e. E )
17		eqid	\|- ( Base ` F ) = ( Base ` F )
18	2 4 6 7 17	dvhbase	\|- ( ( K e. HL /\ W e. H ) -> ( Base ` F ) = E )
19	9 18	syl	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( Base ` F ) = E )
20	16 19	eleqtrrd	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> S e. ( Base ` F ) )
21		simp3	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> S =/= O )
22	11	fveq2d	\|- ( ( K e. HL /\ W e. H ) -> ( 0g ` F ) = ( 0g ` ( ( EDRing ` K ) ` W ) ) )
23		eqid	\|- ( 0g ` ( ( EDRing ` K ) ` W ) ) = ( 0g ` ( ( EDRing ` K ) ` W ) )
24	1 2 3 10 5 23	erng0g	\|- ( ( K e. HL /\ W e. H ) -> ( 0g ` ( ( EDRing ` K ) ` W ) ) = O )
25	22 24	eqtrd	\|- ( ( K e. HL /\ W e. H ) -> ( 0g ` F ) = O )
26	9 25	syl	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( 0g ` F ) = O )
27	21 26	neeqtrrd	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> S =/= ( 0g ` F ) )
28		eqid	\|- ( 0g ` F ) = ( 0g ` F )
29		eqid	\|- ( .r ` F ) = ( .r ` F )
30		eqid	\|- ( 1r ` F ) = ( 1r ` F )
31	17 28 29 30 8	drnginvrl	\|- ( ( F e. DivRing /\ S e. ( Base ` F ) /\ S =/= ( 0g ` F ) ) -> ( ( N ` S ) ( .r ` F ) S ) = ( 1r ` F ) )
32	15 20 27 31	syl3anc	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( ( N ` S ) ( .r ` F ) S ) = ( 1r ` F ) )
33	1 2 3 4 5 6 7 8	tendoinvcl	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( ( N ` S ) e. E /\ ( N ` S ) =/= O ) )
34	33	simpld	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( N ` S ) e. E )
35	2 3 4 6 7 29	dvhmulr	\|- ( ( ( K e. HL /\ W e. H ) /\ ( ( N ` S ) e. E /\ S e. E ) ) -> ( ( N ` S ) ( .r ` F ) S ) = ( ( N ` S ) o. S ) )
36	9 34 16 35	syl12anc	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( ( N ` S ) ( .r ` F ) S ) = ( ( N ` S ) o. S ) )
37	11	fveq2d	\|- ( ( K e. HL /\ W e. H ) -> ( 1r ` F ) = ( 1r ` ( ( EDRing ` K ) ` W ) ) )
38		eqid	\|- ( 1r ` ( ( EDRing ` K ) ` W ) ) = ( 1r ` ( ( EDRing ` K ) ` W ) )
39	2 3 10 38	erng1r	\|- ( ( K e. HL /\ W e. H ) -> ( 1r ` ( ( EDRing ` K ) ` W ) ) = ( _I \|` T ) )
40	37 39	eqtrd	\|- ( ( K e. HL /\ W e. H ) -> ( 1r ` F ) = ( _I \|` T ) )
41	9 40	syl	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( 1r ` F ) = ( _I \|` T ) )
42	32 36 41	3eqtr3d	\|- ( ( ( K e. HL /\ W e. H ) /\ S e. E /\ S =/= O ) -> ( ( N ` S ) o. S ) = ( _I \|` T ) )

Metamath Proof Explorer

Theorem tendolinv

Proof