mapdh6fN

Description: Lemmma for mapdh6N . Part (6) in Baer p. 47 line 38. (Contributed by NM, 1-May-2015) (New usage is discouraged.)

	Ref	Expression
Hypotheses	mapdh.q	\|- Q = ( 0g ` C )
	mapdh.i	\|- I = ( x e. _V \|-> if ( ( 2nd ` x ) = .0. , Q , ( iota_ h e. D ( ( M ` ( N ` { ( 2nd ` x ) } ) ) = ( J ` { h } ) /\ ( M ` ( N ` { ( ( 1st ` ( 1st ` x ) ) .- ( 2nd ` x ) ) } ) ) = ( J ` { ( ( 2nd ` ( 1st ` x ) ) R h ) } ) ) ) ) )
	mapdh.h	\|- H = ( LHyp ` K )
	mapdh.m	\|- M = ( ( mapd ` K ) ` W )
	mapdh.u	\|- U = ( ( DVecH ` K ) ` W )
	mapdh.v	\|- V = ( Base ` U )
	mapdh.s	\|- .- = ( -g ` U )
	mapdhc.o	\|- .0. = ( 0g ` U )
	mapdh.n	\|- N = ( LSpan ` U )
	mapdh.c	\|- C = ( ( LCDual ` K ) ` W )
	mapdh.d	\|- D = ( Base ` C )
	mapdh.r	\|- R = ( -g ` C )
	mapdh.j	\|- J = ( LSpan ` C )
	mapdh.k	\|- ( ph -> ( K e. HL /\ W e. H ) )
	mapdhc.f	\|- ( ph -> F e. D )
	mapdh.mn	\|- ( ph -> ( M ` ( N ` { X } ) ) = ( J ` { F } ) )
	mapdhcl.x	\|- ( ph -> X e. ( V \ { .0. } ) )
	mapdh.p	\|- .+ = ( +g ` U )
	mapdh.a	\|- .+b = ( +g ` C )
	mapdh6d.xn	\|- ( ph -> -. X e. ( N ` { Y , Z } ) )
	mapdh6d.yz	\|- ( ph -> ( N ` { Y } ) = ( N ` { Z } ) )
	mapdh6d.y	\|- ( ph -> Y e. ( V \ { .0. } ) )
	mapdh6d.z	\|- ( ph -> Z e. ( V \ { .0. } ) )
	mapdh6d.w	\|- ( ph -> w e. ( V \ { .0. } ) )
	mapdh6d.wn	\|- ( ph -> -. w e. ( N ` { X , Y } ) )
Assertion	mapdh6fN	\|- ( ph -> ( I ` <. X , F , ( w .+ Y ) >. ) = ( ( I ` <. X , F , w >. ) .+b ( I ` <. X , F , Y >. ) ) )

Proof

Step	Hyp	Ref	Expression
1		mapdh.q	\|- Q = ( 0g ` C )
2		mapdh.i	\|- I = ( x e. _V \|-> if ( ( 2nd ` x ) = .0. , Q , ( iota_ h e. D ( ( M ` ( N ` { ( 2nd ` x ) } ) ) = ( J ` { h } ) /\ ( M ` ( N ` { ( ( 1st ` ( 1st ` x ) ) .- ( 2nd ` x ) ) } ) ) = ( J ` { ( ( 2nd ` ( 1st ` x ) ) R h ) } ) ) ) ) )
3		mapdh.h	\|- H = ( LHyp ` K )
4		mapdh.m	\|- M = ( ( mapd ` K ) ` W )
5		mapdh.u	\|- U = ( ( DVecH ` K ) ` W )
6		mapdh.v	\|- V = ( Base ` U )
7		mapdh.s	\|- .- = ( -g ` U )
8		mapdhc.o	\|- .0. = ( 0g ` U )
9		mapdh.n	\|- N = ( LSpan ` U )
10		mapdh.c	\|- C = ( ( LCDual ` K ) ` W )
11		mapdh.d	\|- D = ( Base ` C )
12		mapdh.r	\|- R = ( -g ` C )
13		mapdh.j	\|- J = ( LSpan ` C )
14		mapdh.k	\|- ( ph -> ( K e. HL /\ W e. H ) )
15		mapdhc.f	\|- ( ph -> F e. D )
16		mapdh.mn	\|- ( ph -> ( M ` ( N ` { X } ) ) = ( J ` { F } ) )
17		mapdhcl.x	\|- ( ph -> X e. ( V \ { .0. } ) )
18		mapdh.p	\|- .+ = ( +g ` U )
19		mapdh.a	\|- .+b = ( +g ` C )
20		mapdh6d.xn	\|- ( ph -> -. X e. ( N ` { Y , Z } ) )
21		mapdh6d.yz	\|- ( ph -> ( N ` { Y } ) = ( N ` { Z } ) )
22		mapdh6d.y	\|- ( ph -> Y e. ( V \ { .0. } ) )
23		mapdh6d.z	\|- ( ph -> Z e. ( V \ { .0. } ) )
24		mapdh6d.w	\|- ( ph -> w e. ( V \ { .0. } ) )
25		mapdh6d.wn	\|- ( ph -> -. w e. ( N ` { X , Y } ) )
26	3 5 14	dvhlvec	\|- ( ph -> U e. LVec )
27	22	eldifad	\|- ( ph -> Y e. V )
28	24	eldifad	\|- ( ph -> w e. V )
29	17	eldifad	\|- ( ph -> X e. V )
30	23	eldifad	\|- ( ph -> Z e. V )
31	6 9 26 29 27 30 20	lspindpi	\|- ( ph -> ( ( N ` { X } ) =/= ( N ` { Y } ) /\ ( N ` { X } ) =/= ( N ` { Z } ) ) )
32	31	simpld	\|- ( ph -> ( N ` { X } ) =/= ( N ` { Y } ) )
33	6 8 9 26 17 27 28 32 25	lspindp1	\|- ( ph -> ( ( N ` { w } ) =/= ( N ` { Y } ) /\ -. X e. ( N ` { w , Y } ) ) )
34	33	simprd	\|- ( ph -> -. X e. ( N ` { w , Y } ) )
35	6 9 26 28 29 27 25	lspindpi	\|- ( ph -> ( ( N ` { w } ) =/= ( N ` { X } ) /\ ( N ` { w } ) =/= ( N ` { Y } ) ) )
36	35	simprd	\|- ( ph -> ( N ` { w } ) =/= ( N ` { Y } ) )
37		eqidd	\|- ( ph -> ( I ` <. X , F , w >. ) = ( I ` <. X , F , w >. ) )
38		eqidd	\|- ( ph -> ( I ` <. X , F , Y >. ) = ( I ` <. X , F , Y >. ) )
39	1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 24 22 34 36 37 38	mapdh6aN	\|- ( ph -> ( I ` <. X , F , ( w .+ Y ) >. ) = ( ( I ` <. X , F , w >. ) .+b ( I ` <. X , F , Y >. ) ) )

Metamath Proof Explorer

Theorem mapdh6fN

Proof