cdleme2

Description: Part of proof of Lemma E in Crawley p. 113. F represents f(r). W is the fiducial co-atom (hyperplane) w. Here we show that (r \/ f(r)) /\ w = u in their notation (4th line from bottom on p. 113). (Contributed by NM, 5-Jun-2012)

	Ref	Expression
Hypotheses	cdleme1.l	\|- .<_ = ( le ` K )
	cdleme1.j	\|- .\/ = ( join ` K )
	cdleme1.m	\|- ./\ = ( meet ` K )
	cdleme1.a	\|- A = ( Atoms ` K )
	cdleme1.h	\|- H = ( LHyp ` K )
	cdleme1.u	\|- U = ( ( P .\/ Q ) ./\ W )
	cdleme1.f	\|- F = ( ( R .\/ U ) ./\ ( Q .\/ ( ( P .\/ R ) ./\ W ) ) )
Assertion	cdleme2	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( ( R .\/ F ) ./\ W ) = U )

Proof

Step	Hyp	Ref	Expression
1		cdleme1.l	\|- .<_ = ( le ` K )
2		cdleme1.j	\|- .\/ = ( join ` K )
3		cdleme1.m	\|- ./\ = ( meet ` K )
4		cdleme1.a	\|- A = ( Atoms ` K )
5		cdleme1.h	\|- H = ( LHyp ` K )
6		cdleme1.u	\|- U = ( ( P .\/ Q ) ./\ W )
7		cdleme1.f	\|- F = ( ( R .\/ U ) ./\ ( Q .\/ ( ( P .\/ R ) ./\ W ) ) )
8	1 2 3 4 5 6 7	cdleme1	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( R .\/ F ) = ( R .\/ U ) )
9	8	oveq1d	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( ( R .\/ F ) ./\ W ) = ( ( R .\/ U ) ./\ W ) )
10		simpll	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> K e. HL )
11		simpr3l	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> R e. A )
12		hllat	\|- ( K e. HL -> K e. Lat )
13	12	ad2antrr	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> K e. Lat )
14		simpr1	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> P e. A )
15		eqid	\|- ( Base ` K ) = ( Base ` K )
16	15 4	atbase	\|- ( P e. A -> P e. ( Base ` K ) )
17	14 16	syl	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> P e. ( Base ` K ) )
18		simpr2	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> Q e. A )
19	15 4	atbase	\|- ( Q e. A -> Q e. ( Base ` K ) )
20	18 19	syl	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> Q e. ( Base ` K ) )
21	15 2	latjcl	\|- ( ( K e. Lat /\ P e. ( Base ` K ) /\ Q e. ( Base ` K ) ) -> ( P .\/ Q ) e. ( Base ` K ) )
22	13 17 20 21	syl3anc	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( P .\/ Q ) e. ( Base ` K ) )
23	15 5	lhpbase	\|- ( W e. H -> W e. ( Base ` K ) )
24	23	ad2antlr	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> W e. ( Base ` K ) )
25	15 3	latmcl	\|- ( ( K e. Lat /\ ( P .\/ Q ) e. ( Base ` K ) /\ W e. ( Base ` K ) ) -> ( ( P .\/ Q ) ./\ W ) e. ( Base ` K ) )
26	13 22 24 25	syl3anc	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( ( P .\/ Q ) ./\ W ) e. ( Base ` K ) )
27	6 26	eqeltrid	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> U e. ( Base ` K ) )
28	15 1 3	latmle2	\|- ( ( K e. Lat /\ ( P .\/ Q ) e. ( Base ` K ) /\ W e. ( Base ` K ) ) -> ( ( P .\/ Q ) ./\ W ) .<_ W )
29	13 22 24 28	syl3anc	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( ( P .\/ Q ) ./\ W ) .<_ W )
30	6 29	eqbrtrid	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> U .<_ W )
31	15 1 2 3 4	atmod4i2	\|- ( ( K e. HL /\ ( R e. A /\ U e. ( Base ` K ) /\ W e. ( Base ` K ) ) /\ U .<_ W ) -> ( ( R ./\ W ) .\/ U ) = ( ( R .\/ U ) ./\ W ) )
32	10 11 27 24 30 31	syl131anc	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( ( R ./\ W ) .\/ U ) = ( ( R .\/ U ) ./\ W ) )
33		eqid	\|- ( 0. ` K ) = ( 0. ` K )
34	1 3 33 4 5	lhpmat	\|- ( ( ( K e. HL /\ W e. H ) /\ ( R e. A /\ -. R .<_ W ) ) -> ( R ./\ W ) = ( 0. ` K ) )
35	34	3ad2antr3	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( R ./\ W ) = ( 0. ` K ) )
36	35	oveq1d	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( ( R ./\ W ) .\/ U ) = ( ( 0. ` K ) .\/ U ) )
37		hlol	\|- ( K e. HL -> K e. OL )
38	37	ad2antrr	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> K e. OL )
39	15 2 33	olj02	\|- ( ( K e. OL /\ U e. ( Base ` K ) ) -> ( ( 0. ` K ) .\/ U ) = U )
40	38 27 39	syl2anc	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( ( 0. ` K ) .\/ U ) = U )
41	36 40	eqtrd	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( ( R ./\ W ) .\/ U ) = U )
42	9 32 41	3eqtr2d	\|- ( ( ( K e. HL /\ W e. H ) /\ ( P e. A /\ Q e. A /\ ( R e. A /\ -. R .<_ W ) ) ) -> ( ( R .\/ F ) ./\ W ) = U )

Metamath Proof Explorer

Theorem cdleme2

Proof