dihglblem2aN

Description: Lemma for isomorphism H of a GLB. (Contributed by NM, 19-Mar-2014) (New usage is discouraged.)

	Ref	Expression
Hypotheses	dihglblem.b	\|- B = ( Base ` K )
	dihglblem.l	\|- .<_ = ( le ` K )
	dihglblem.m	\|- ./\ = ( meet ` K )
	dihglblem.g	\|- G = ( glb ` K )
	dihglblem.h	\|- H = ( LHyp ` K )
	dihglblem.t	\|- T = { u e. B \| E. v e. S u = ( v ./\ W ) }
Assertion	dihglblem2aN	\|- ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) -> T =/= (/) )

Proof

Step	Hyp	Ref	Expression
1		dihglblem.b	\|- B = ( Base ` K )
2		dihglblem.l	\|- .<_ = ( le ` K )
3		dihglblem.m	\|- ./\ = ( meet ` K )
4		dihglblem.g	\|- G = ( glb ` K )
5		dihglblem.h	\|- H = ( LHyp ` K )
6		dihglblem.t	\|- T = { u e. B \| E. v e. S u = ( v ./\ W ) }
7	6	a1i	\|- ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) -> T = { u e. B \| E. v e. S u = ( v ./\ W ) } )
8		simprr	\|- ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) -> S =/= (/) )
9		n0	\|- ( S =/= (/) <-> E. z z e. S )
10	8 9	sylib	\|- ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) -> E. z z e. S )
11		hllat	\|- ( K e. HL -> K e. Lat )
12	11	ad3antrrr	\|- ( ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) /\ z e. S ) -> K e. Lat )
13		simplrl	\|- ( ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) /\ z e. S ) -> S C_ B )
14		simpr	\|- ( ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) /\ z e. S ) -> z e. S )
15	13 14	sseldd	\|- ( ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) /\ z e. S ) -> z e. B )
16	1 5	lhpbase	\|- ( W e. H -> W e. B )
17	16	ad3antlr	\|- ( ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) /\ z e. S ) -> W e. B )
18	1 3	latmcl	\|- ( ( K e. Lat /\ z e. B /\ W e. B ) -> ( z ./\ W ) e. B )
19	12 15 17 18	syl3anc	\|- ( ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) /\ z e. S ) -> ( z ./\ W ) e. B )
20		eqidd	\|- ( ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) /\ z e. S ) -> ( z ./\ W ) = ( z ./\ W ) )
21		oveq1	\|- ( v = z -> ( v ./\ W ) = ( z ./\ W ) )
22	21	rspceeqv	\|- ( ( z e. S /\ ( z ./\ W ) = ( z ./\ W ) ) -> E. v e. S ( z ./\ W ) = ( v ./\ W ) )
23	14 20 22	syl2anc	\|- ( ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) /\ z e. S ) -> E. v e. S ( z ./\ W ) = ( v ./\ W ) )
24		ovex	\|- ( z ./\ W ) e. _V
25		eleq1	\|- ( w = ( z ./\ W ) -> ( w e. { u e. B \| E. v e. S u = ( v ./\ W ) } <-> ( z ./\ W ) e. { u e. B \| E. v e. S u = ( v ./\ W ) } ) )
26		eqeq1	\|- ( u = ( z ./\ W ) -> ( u = ( v ./\ W ) <-> ( z ./\ W ) = ( v ./\ W ) ) )
27	26	rexbidv	\|- ( u = ( z ./\ W ) -> ( E. v e. S u = ( v ./\ W ) <-> E. v e. S ( z ./\ W ) = ( v ./\ W ) ) )
28	27	elrab	\|- ( ( z ./\ W ) e. { u e. B \| E. v e. S u = ( v ./\ W ) } <-> ( ( z ./\ W ) e. B /\ E. v e. S ( z ./\ W ) = ( v ./\ W ) ) )
29	25 28	bitrdi	\|- ( w = ( z ./\ W ) -> ( w e. { u e. B \| E. v e. S u = ( v ./\ W ) } <-> ( ( z ./\ W ) e. B /\ E. v e. S ( z ./\ W ) = ( v ./\ W ) ) ) )
30	24 29	spcev	\|- ( ( ( z ./\ W ) e. B /\ E. v e. S ( z ./\ W ) = ( v ./\ W ) ) -> E. w w e. { u e. B \| E. v e. S u = ( v ./\ W ) } )
31	19 23 30	syl2anc	\|- ( ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) /\ z e. S ) -> E. w w e. { u e. B \| E. v e. S u = ( v ./\ W ) } )
32		n0	\|- ( { u e. B \| E. v e. S u = ( v ./\ W ) } =/= (/) <-> E. w w e. { u e. B \| E. v e. S u = ( v ./\ W ) } )
33	31 32	sylibr	\|- ( ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) /\ z e. S ) -> { u e. B \| E. v e. S u = ( v ./\ W ) } =/= (/) )
34	10 33	exlimddv	\|- ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) -> { u e. B \| E. v e. S u = ( v ./\ W ) } =/= (/) )
35	7 34	eqnetrd	\|- ( ( ( K e. HL /\ W e. H ) /\ ( S C_ B /\ S =/= (/) ) ) -> T =/= (/) )

Metamath Proof Explorer

Theorem dihglblem2aN

Proof