pol1N

Description: The polarity of the whole projective subspace is the empty space. Remark in Holland95 p. 223. (Contributed by NM, 24-Jan-2012) (New usage is discouraged.)

	Ref	Expression
Hypotheses	polssat.a	\|- A = ( Atoms ` K )
	polssat.p	\|- ._\|_ = ( _\|_P ` K )
Assertion	pol1N	\|- ( K e. HL -> ( ._\|_ ` A ) = (/) )

Proof

Step	Hyp	Ref	Expression
1		polssat.a	\|- A = ( Atoms ` K )
2		polssat.p	\|- ._\|_ = ( _\|_P ` K )
3		ssid	\|- A C_ A
4		eqid	\|- ( lub ` K ) = ( lub ` K )
5		eqid	\|- ( oc ` K ) = ( oc ` K )
6		eqid	\|- ( pmap ` K ) = ( pmap ` K )
7	4 5 1 6 2	polval2N	\|- ( ( K e. HL /\ A C_ A ) -> ( ._\|_ ` A ) = ( ( pmap ` K ) ` ( ( oc ` K ) ` ( ( lub ` K ) ` A ) ) ) )
8	3 7	mpan2	\|- ( K e. HL -> ( ._\|_ ` A ) = ( ( pmap ` K ) ` ( ( oc ` K ) ` ( ( lub ` K ) ` A ) ) ) )
9		hlop	\|- ( K e. HL -> K e. OP )
10		eqid	\|- ( Base ` K ) = ( Base ` K )
11	10 1	atbase	\|- ( p e. A -> p e. ( Base ` K ) )
12		eqid	\|- ( le ` K ) = ( le ` K )
13		eqid	\|- ( 1. ` K ) = ( 1. ` K )
14	10 12 13	ople1	\|- ( ( K e. OP /\ p e. ( Base ` K ) ) -> p ( le ` K ) ( 1. ` K ) )
15	9 11 14	syl2an	\|- ( ( K e. HL /\ p e. A ) -> p ( le ` K ) ( 1. ` K ) )
16	15	ralrimiva	\|- ( K e. HL -> A. p e. A p ( le ` K ) ( 1. ` K ) )
17		rabid2	\|- ( A = { p e. A \| p ( le ` K ) ( 1. ` K ) } <-> A. p e. A p ( le ` K ) ( 1. ` K ) )
18	16 17	sylibr	\|- ( K e. HL -> A = { p e. A \| p ( le ` K ) ( 1. ` K ) } )
19	18	fveq2d	\|- ( K e. HL -> ( ( lub ` K ) ` A ) = ( ( lub ` K ) ` { p e. A \| p ( le ` K ) ( 1. ` K ) } ) )
20		hlomcmat	\|- ( K e. HL -> ( K e. OML /\ K e. CLat /\ K e. AtLat ) )
21	10 13	op1cl	\|- ( K e. OP -> ( 1. ` K ) e. ( Base ` K ) )
22	9 21	syl	\|- ( K e. HL -> ( 1. ` K ) e. ( Base ` K ) )
23	10 12 4 1	atlatmstc	\|- ( ( ( K e. OML /\ K e. CLat /\ K e. AtLat ) /\ ( 1. ` K ) e. ( Base ` K ) ) -> ( ( lub ` K ) ` { p e. A \| p ( le ` K ) ( 1. ` K ) } ) = ( 1. ` K ) )
24	20 22 23	syl2anc	\|- ( K e. HL -> ( ( lub ` K ) ` { p e. A \| p ( le ` K ) ( 1. ` K ) } ) = ( 1. ` K ) )
25	19 24	eqtr2d	\|- ( K e. HL -> ( 1. ` K ) = ( ( lub ` K ) ` A ) )
26	25	fveq2d	\|- ( K e. HL -> ( ( oc ` K ) ` ( 1. ` K ) ) = ( ( oc ` K ) ` ( ( lub ` K ) ` A ) ) )
27		eqid	\|- ( 0. ` K ) = ( 0. ` K )
28	27 13 5	opoc1	\|- ( K e. OP -> ( ( oc ` K ) ` ( 1. ` K ) ) = ( 0. ` K ) )
29	9 28	syl	\|- ( K e. HL -> ( ( oc ` K ) ` ( 1. ` K ) ) = ( 0. ` K ) )
30	26 29	eqtr3d	\|- ( K e. HL -> ( ( oc ` K ) ` ( ( lub ` K ) ` A ) ) = ( 0. ` K ) )
31	30	fveq2d	\|- ( K e. HL -> ( ( pmap ` K ) ` ( ( oc ` K ) ` ( ( lub ` K ) ` A ) ) ) = ( ( pmap ` K ) ` ( 0. ` K ) ) )
32		hlatl	\|- ( K e. HL -> K e. AtLat )
33	27 6	pmap0	\|- ( K e. AtLat -> ( ( pmap ` K ) ` ( 0. ` K ) ) = (/) )
34	32 33	syl	\|- ( K e. HL -> ( ( pmap ` K ) ` ( 0. ` K ) ) = (/) )
35	8 31 34	3eqtrd	\|- ( K e. HL -> ( ._\|_ ` A ) = (/) )

Metamath Proof Explorer

Theorem pol1N

Proof