dalem58

Description: Lemma for dath . Analogue of dalem57 for E . (Contributed by NM, 10-Aug-2012)

	Ref	Expression
Hypotheses	dalem.ph	\|- ( ph <-> ( ( ( K e. HL /\ C e. ( Base ` K ) ) /\ ( P e. A /\ Q e. A /\ R e. A ) /\ ( S e. A /\ T e. A /\ U e. A ) ) /\ ( Y e. O /\ Z e. O ) /\ ( ( -. C .<_ ( P .\/ Q ) /\ -. C .<_ ( Q .\/ R ) /\ -. C .<_ ( R .\/ P ) ) /\ ( -. C .<_ ( S .\/ T ) /\ -. C .<_ ( T .\/ U ) /\ -. C .<_ ( U .\/ S ) ) /\ ( C .<_ ( P .\/ S ) /\ C .<_ ( Q .\/ T ) /\ C .<_ ( R .\/ U ) ) ) ) )
	dalem.l	\|- .<_ = ( le ` K )
	dalem.j	\|- .\/ = ( join ` K )
	dalem.a	\|- A = ( Atoms ` K )
	dalem.ps	\|- ( ps <-> ( ( c e. A /\ d e. A ) /\ -. c .<_ Y /\ ( d =/= c /\ -. d .<_ Y /\ C .<_ ( c .\/ d ) ) ) )
	dalem58.m	\|- ./\ = ( meet ` K )
	dalem58.o	\|- O = ( LPlanes ` K )
	dalem58.y	\|- Y = ( ( P .\/ Q ) .\/ R )
	dalem58.z	\|- Z = ( ( S .\/ T ) .\/ U )
	dalem58.e	\|- E = ( ( Q .\/ R ) ./\ ( T .\/ U ) )
	dalem58.g	\|- G = ( ( c .\/ P ) ./\ ( d .\/ S ) )
	dalem58.h	\|- H = ( ( c .\/ Q ) ./\ ( d .\/ T ) )
	dalem58.i	\|- I = ( ( c .\/ R ) ./\ ( d .\/ U ) )
	dalem58.b1	\|- B = ( ( ( G .\/ H ) .\/ I ) ./\ Y )
Assertion	dalem58	\|- ( ( ph /\ Y = Z /\ ps ) -> E .<_ B )

Proof

Step	Hyp	Ref	Expression
1		dalem.ph	\|- ( ph <-> ( ( ( K e. HL /\ C e. ( Base ` K ) ) /\ ( P e. A /\ Q e. A /\ R e. A ) /\ ( S e. A /\ T e. A /\ U e. A ) ) /\ ( Y e. O /\ Z e. O ) /\ ( ( -. C .<_ ( P .\/ Q ) /\ -. C .<_ ( Q .\/ R ) /\ -. C .<_ ( R .\/ P ) ) /\ ( -. C .<_ ( S .\/ T ) /\ -. C .<_ ( T .\/ U ) /\ -. C .<_ ( U .\/ S ) ) /\ ( C .<_ ( P .\/ S ) /\ C .<_ ( Q .\/ T ) /\ C .<_ ( R .\/ U ) ) ) ) )
2		dalem.l	\|- .<_ = ( le ` K )
3		dalem.j	\|- .\/ = ( join ` K )
4		dalem.a	\|- A = ( Atoms ` K )
5		dalem.ps	\|- ( ps <-> ( ( c e. A /\ d e. A ) /\ -. c .<_ Y /\ ( d =/= c /\ -. d .<_ Y /\ C .<_ ( c .\/ d ) ) ) )
6		dalem58.m	\|- ./\ = ( meet ` K )
7		dalem58.o	\|- O = ( LPlanes ` K )
8		dalem58.y	\|- Y = ( ( P .\/ Q ) .\/ R )
9		dalem58.z	\|- Z = ( ( S .\/ T ) .\/ U )
10		dalem58.e	\|- E = ( ( Q .\/ R ) ./\ ( T .\/ U ) )
11		dalem58.g	\|- G = ( ( c .\/ P ) ./\ ( d .\/ S ) )
12		dalem58.h	\|- H = ( ( c .\/ Q ) ./\ ( d .\/ T ) )
13		dalem58.i	\|- I = ( ( c .\/ R ) ./\ ( d .\/ U ) )
14		dalem58.b1	\|- B = ( ( ( G .\/ H ) .\/ I ) ./\ Y )
15	1 2 3 4 8 9	dalemrot	\|- ( ph -> ( ( ( K e. HL /\ C e. ( Base ` K ) ) /\ ( Q e. A /\ R e. A /\ P e. A ) /\ ( T e. A /\ U e. A /\ S e. A ) ) /\ ( ( ( Q .\/ R ) .\/ P ) e. O /\ ( ( T .\/ U ) .\/ S ) e. O ) /\ ( ( -. C .<_ ( Q .\/ R ) /\ -. C .<_ ( R .\/ P ) /\ -. C .<_ ( P .\/ Q ) ) /\ ( -. C .<_ ( T .\/ U ) /\ -. C .<_ ( U .\/ S ) /\ -. C .<_ ( S .\/ T ) ) /\ ( C .<_ ( Q .\/ T ) /\ C .<_ ( R .\/ U ) /\ C .<_ ( P .\/ S ) ) ) ) )
16	15	3ad2ant1	\|- ( ( ph /\ Y = Z /\ ps ) -> ( ( ( K e. HL /\ C e. ( Base ` K ) ) /\ ( Q e. A /\ R e. A /\ P e. A ) /\ ( T e. A /\ U e. A /\ S e. A ) ) /\ ( ( ( Q .\/ R ) .\/ P ) e. O /\ ( ( T .\/ U ) .\/ S ) e. O ) /\ ( ( -. C .<_ ( Q .\/ R ) /\ -. C .<_ ( R .\/ P ) /\ -. C .<_ ( P .\/ Q ) ) /\ ( -. C .<_ ( T .\/ U ) /\ -. C .<_ ( U .\/ S ) /\ -. C .<_ ( S .\/ T ) ) /\ ( C .<_ ( Q .\/ T ) /\ C .<_ ( R .\/ U ) /\ C .<_ ( P .\/ S ) ) ) ) )
17	1 2 3 4 8 9	dalemrotyz	\|- ( ( ph /\ Y = Z ) -> ( ( Q .\/ R ) .\/ P ) = ( ( T .\/ U ) .\/ S ) )
18	17	3adant3	\|- ( ( ph /\ Y = Z /\ ps ) -> ( ( Q .\/ R ) .\/ P ) = ( ( T .\/ U ) .\/ S ) )
19	1 2 3 4 5 8	dalemrotps	\|- ( ( ph /\ ps ) -> ( ( c e. A /\ d e. A ) /\ -. c .<_ ( ( Q .\/ R ) .\/ P ) /\ ( d =/= c /\ -. d .<_ ( ( Q .\/ R ) .\/ P ) /\ C .<_ ( c .\/ d ) ) ) )
20	19	3adant2	\|- ( ( ph /\ Y = Z /\ ps ) -> ( ( c e. A /\ d e. A ) /\ -. c .<_ ( ( Q .\/ R ) .\/ P ) /\ ( d =/= c /\ -. d .<_ ( ( Q .\/ R ) .\/ P ) /\ C .<_ ( c .\/ d ) ) ) )
21		biid	\|- ( ( ( ( K e. HL /\ C e. ( Base ` K ) ) /\ ( Q e. A /\ R e. A /\ P e. A ) /\ ( T e. A /\ U e. A /\ S e. A ) ) /\ ( ( ( Q .\/ R ) .\/ P ) e. O /\ ( ( T .\/ U ) .\/ S ) e. O ) /\ ( ( -. C .<_ ( Q .\/ R ) /\ -. C .<_ ( R .\/ P ) /\ -. C .<_ ( P .\/ Q ) ) /\ ( -. C .<_ ( T .\/ U ) /\ -. C .<_ ( U .\/ S ) /\ -. C .<_ ( S .\/ T ) ) /\ ( C .<_ ( Q .\/ T ) /\ C .<_ ( R .\/ U ) /\ C .<_ ( P .\/ S ) ) ) ) <-> ( ( ( K e. HL /\ C e. ( Base ` K ) ) /\ ( Q e. A /\ R e. A /\ P e. A ) /\ ( T e. A /\ U e. A /\ S e. A ) ) /\ ( ( ( Q .\/ R ) .\/ P ) e. O /\ ( ( T .\/ U ) .\/ S ) e. O ) /\ ( ( -. C .<_ ( Q .\/ R ) /\ -. C .<_ ( R .\/ P ) /\ -. C .<_ ( P .\/ Q ) ) /\ ( -. C .<_ ( T .\/ U ) /\ -. C .<_ ( U .\/ S ) /\ -. C .<_ ( S .\/ T ) ) /\ ( C .<_ ( Q .\/ T ) /\ C .<_ ( R .\/ U ) /\ C .<_ ( P .\/ S ) ) ) ) )
22		biid	\|- ( ( ( c e. A /\ d e. A ) /\ -. c .<_ ( ( Q .\/ R ) .\/ P ) /\ ( d =/= c /\ -. d .<_ ( ( Q .\/ R ) .\/ P ) /\ C .<_ ( c .\/ d ) ) ) <-> ( ( c e. A /\ d e. A ) /\ -. c .<_ ( ( Q .\/ R ) .\/ P ) /\ ( d =/= c /\ -. d .<_ ( ( Q .\/ R ) .\/ P ) /\ C .<_ ( c .\/ d ) ) ) )
23		eqid	\|- ( ( Q .\/ R ) .\/ P ) = ( ( Q .\/ R ) .\/ P )
24		eqid	\|- ( ( T .\/ U ) .\/ S ) = ( ( T .\/ U ) .\/ S )
25		eqid	\|- ( ( ( H .\/ I ) .\/ G ) ./\ ( ( Q .\/ R ) .\/ P ) ) = ( ( ( H .\/ I ) .\/ G ) ./\ ( ( Q .\/ R ) .\/ P ) )
26	21 2 3 4 22 6 7 23 24 10 12 13 11 25	dalem57	\|- ( ( ( ( ( K e. HL /\ C e. ( Base ` K ) ) /\ ( Q e. A /\ R e. A /\ P e. A ) /\ ( T e. A /\ U e. A /\ S e. A ) ) /\ ( ( ( Q .\/ R ) .\/ P ) e. O /\ ( ( T .\/ U ) .\/ S ) e. O ) /\ ( ( -. C .<_ ( Q .\/ R ) /\ -. C .<_ ( R .\/ P ) /\ -. C .<_ ( P .\/ Q ) ) /\ ( -. C .<_ ( T .\/ U ) /\ -. C .<_ ( U .\/ S ) /\ -. C .<_ ( S .\/ T ) ) /\ ( C .<_ ( Q .\/ T ) /\ C .<_ ( R .\/ U ) /\ C .<_ ( P .\/ S ) ) ) ) /\ ( ( Q .\/ R ) .\/ P ) = ( ( T .\/ U ) .\/ S ) /\ ( ( c e. A /\ d e. A ) /\ -. c .<_ ( ( Q .\/ R ) .\/ P ) /\ ( d =/= c /\ -. d .<_ ( ( Q .\/ R ) .\/ P ) /\ C .<_ ( c .\/ d ) ) ) ) -> E .<_ ( ( ( H .\/ I ) .\/ G ) ./\ ( ( Q .\/ R ) .\/ P ) ) )
27	16 18 20 26	syl3anc	\|- ( ( ph /\ Y = Z /\ ps ) -> E .<_ ( ( ( H .\/ I ) .\/ G ) ./\ ( ( Q .\/ R ) .\/ P ) ) )
28	1	dalemkehl	\|- ( ph -> K e. HL )
29	28	3ad2ant1	\|- ( ( ph /\ Y = Z /\ ps ) -> K e. HL )
30	1 2 3 4 5 6 7 8 9 12	dalem29	\|- ( ( ph /\ Y = Z /\ ps ) -> H e. A )
31	1 2 3 4 5 6 7 8 9 13	dalem34	\|- ( ( ph /\ Y = Z /\ ps ) -> I e. A )
32	1 2 3 4 5 6 7 8 9 11	dalem23	\|- ( ( ph /\ Y = Z /\ ps ) -> G e. A )
33	3 4	hlatjrot	\|- ( ( K e. HL /\ ( H e. A /\ I e. A /\ G e. A ) ) -> ( ( H .\/ I ) .\/ G ) = ( ( G .\/ H ) .\/ I ) )
34	29 30 31 32 33	syl13anc	\|- ( ( ph /\ Y = Z /\ ps ) -> ( ( H .\/ I ) .\/ G ) = ( ( G .\/ H ) .\/ I ) )
35	1 3 4	dalemqrprot	\|- ( ph -> ( ( Q .\/ R ) .\/ P ) = ( ( P .\/ Q ) .\/ R ) )
36	35 8	eqtr4di	\|- ( ph -> ( ( Q .\/ R ) .\/ P ) = Y )
37	36	3ad2ant1	\|- ( ( ph /\ Y = Z /\ ps ) -> ( ( Q .\/ R ) .\/ P ) = Y )
38	34 37	oveq12d	\|- ( ( ph /\ Y = Z /\ ps ) -> ( ( ( H .\/ I ) .\/ G ) ./\ ( ( Q .\/ R ) .\/ P ) ) = ( ( ( G .\/ H ) .\/ I ) ./\ Y ) )
39	38 14	eqtr4di	\|- ( ( ph /\ Y = Z /\ ps ) -> ( ( ( H .\/ I ) .\/ G ) ./\ ( ( Q .\/ R ) .\/ P ) ) = B )
40	27 39	breqtrd	\|- ( ( ph /\ Y = Z /\ ps ) -> E .<_ B )

Metamath Proof Explorer

Theorem dalem58

Proof