dihord2cN

Description: Part of proof after Lemma N of Crawley p. 122. Reverse ordering property. TODO: needed? shorten other proof with it? (Contributed by NM, 3-Mar-2014) (New usage is discouraged.)

	Ref	Expression
Hypotheses	dihjust.b	\|- B = ( Base ` K )
	dihjust.l	\|- .<_ = ( le ` K )
	dihjust.j	\|- .\/ = ( join ` K )
	dihjust.m	\|- ./\ = ( meet ` K )
	dihjust.a	\|- A = ( Atoms ` K )
	dihjust.h	\|- H = ( LHyp ` K )
	dihjust.i	\|- I = ( ( DIsoB ` K ) ` W )
	dihjust.J	\|- J = ( ( DIsoC ` K ) ` W )
	dihjust.u	\|- U = ( ( DVecH ` K ) ` W )
	dihjust.s	\|- .(+) = ( LSSum ` U )
	dihord2c.t	\|- T = ( ( LTrn ` K ) ` W )
	dihord2c.r	\|- R = ( ( trL ` K ) ` W )
	dihord2c.o	\|- O = ( h e. T \|-> ( _I \|` B ) )
Assertion	dihord2cN	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> <. f , O >. e. ( I ` ( X ./\ W ) ) )

Proof

Step	Hyp	Ref	Expression
1		dihjust.b	\|- B = ( Base ` K )
2		dihjust.l	\|- .<_ = ( le ` K )
3		dihjust.j	\|- .\/ = ( join ` K )
4		dihjust.m	\|- ./\ = ( meet ` K )
5		dihjust.a	\|- A = ( Atoms ` K )
6		dihjust.h	\|- H = ( LHyp ` K )
7		dihjust.i	\|- I = ( ( DIsoB ` K ) ` W )
8		dihjust.J	\|- J = ( ( DIsoC ` K ) ` W )
9		dihjust.u	\|- U = ( ( DVecH ` K ) ` W )
10		dihjust.s	\|- .(+) = ( LSSum ` U )
11		dihord2c.t	\|- T = ( ( LTrn ` K ) ` W )
12		dihord2c.r	\|- R = ( ( trL ` K ) ` W )
13		dihord2c.o	\|- O = ( h e. T \|-> ( _I \|` B ) )
14		simp3	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) )
15		eqidd	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> O = O )
16		simp1	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> ( K e. HL /\ W e. H ) )
17		simp1l	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> K e. HL )
18	17	hllatd	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> K e. Lat )
19		simp2	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> X e. B )
20		simp1r	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> W e. H )
21	1 6	lhpbase	\|- ( W e. H -> W e. B )
22	20 21	syl	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> W e. B )
23	1 4	latmcl	\|- ( ( K e. Lat /\ X e. B /\ W e. B ) -> ( X ./\ W ) e. B )
24	18 19 22 23	syl3anc	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> ( X ./\ W ) e. B )
25	1 2 4	latmle2	\|- ( ( K e. Lat /\ X e. B /\ W e. B ) -> ( X ./\ W ) .<_ W )
26	18 19 22 25	syl3anc	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> ( X ./\ W ) .<_ W )
27	1 2 6 11 12 13 7	dibopelval3	\|- ( ( ( K e. HL /\ W e. H ) /\ ( ( X ./\ W ) e. B /\ ( X ./\ W ) .<_ W ) ) -> ( <. f , O >. e. ( I ` ( X ./\ W ) ) <-> ( ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) /\ O = O ) ) )
28	16 24 26 27	syl12anc	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> ( <. f , O >. e. ( I ` ( X ./\ W ) ) <-> ( ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) /\ O = O ) ) )
29	14 15 28	mpbir2and	\|- ( ( ( K e. HL /\ W e. H ) /\ X e. B /\ ( f e. T /\ ( R ` f ) .<_ ( X ./\ W ) ) ) -> <. f , O >. e. ( I ` ( X ./\ W ) ) )

Metamath Proof Explorer

Theorem dihord2cN

Proof