reconsider P = Q as Element of (TOP-REAL 2) ;
A1: |.(P - |[0,0]|).| = |.(|[(P `1),(P `2)]| - |[0,0]|).| by EUCLID:53
.= |.|[((P `1) - 0),((P `2) - 0)]|.| by EUCLID:62
.= |.P.| by EUCLID:53 ;
1 ^2 = 1 ;
then |.P.| ^2 < 1 by TOPREAL9:45, A1, SQUARE_1:16;
then ((P `1) ^2) + ((P `2) ^2) < 1 by JGRAPH_3:1;
then A2: (((P `1) ^2) + ((P `2) ^2)) - 1 < 1 - 1 by XREAL_1:14;
A3: not |[(P `1),(P `2),1]| is zero by EUCLID_5:4, FINSEQ_1:78;
then reconsider R = Dir |[(P `1),(P `2),1]| as Element of (ProjectiveSpace (TOP-REAL 3)) by ANPROJ_1:26;
for u being Element of (TOP-REAL 3) st not u is zero & R = Dir u holds
qfconic (1,1,(- 1),0,0,0,u) is negative

proof

let u be Element of (TOP-REAL 3); :: thesis:
assume that
A4: not u is zero and
A5: R = Dir u ; :: thesis:
are_Prop u,|[(P `1),(P `2),1]| by A3, A4, A5, ANPROJ_1:22;
then consider k being Real such that
A6: k <> 0 and
A7: u = k * |[(P `1),(P `2),1]| by ANPROJ_1:1;
|[(P `1),(P `2),1]| . 1 = |[(P `1),(P `2),1]| `1 by EUCLID_5:def 1
.= P `1 by EUCLID_5:2 ;
then A8: u . 1 = k * (P `1) by A7, RVSUM_1:44;
|[(P `1),(P `2),1]| . 2 = |[(P `1),(P `2),1]| `2 by EUCLID_5:def 2
.= P `2 by EUCLID_5:2 ;
then A9: u . 2 = k * (P `2) by A7, RVSUM_1:44;
|[(P `1),(P `2),1]| . 3 = |[(P `1),(P `2),1]| `3 by EUCLID_5:def 3
.= 1 by EUCLID_5:2 ;
then A10: u . 3 = k * 1 by A7, RVSUM_1:44;
A11: qfconic (1,1,(- 1),0,0,0,u) = ((((((1 * (u . 1)) * (u . 1)) + ((1 * (u . 2)) * (u . 2))) + (((- 1) * (u . 3)) * (u . 3))) + ((0 * (u . 1)) * (u . 2))) + ((0 * (u . 1)) * (u . 3))) + ((0 * (u . 2)) * 1) by PASCAL:def 1
.= (k ^2) * ((((P `1) ^2) + ((P `2) ^2)) - 1) by A8, A9, A10 ;
0 < k ^2 by A6, SQUARE_1:12;
hence qfconic (1,1,(- 1),0,0,0,u) is negative by A11, A2; :: thesis:

end;

then R in { P where P is Point of (ProjectiveSpace (TOP-REAL 3)) : for u being Element of (TOP-REAL 3) st not u is zero & P = Dir u holds
qfconic (1,1,(- 1),0,0,0,u) is negative } ;
hence ex b₁ being Element of BK_model ex P being Element of (TOP-REAL 2) st
( P = Q & b₁ = Dir |[(P `1),(P `2),1]| ) ; :: thesis: