let P be POINT of TarskiEuclid2Space; :: thesis: ( Tn2TR P is Element of inside_of_circle (0,0,1) implies BK_to_T2 (T2_to_BK P) = P )
assume Tn2TR P is Element of inside_of_circle (0,0,1) ; :: thesis: BK_to_T2 (T2_to_BK P) = P
then consider u being non zero Element of (TOP-REAL 3) such that
A1: T2_to_BK P = Dir u and
A2: u `3 = 1 and
A3: Tn2TR P = |[(u `1),(u `2)]| by Def02;
reconsider Q9 = T2_to_BK P as Element of BK-model-Plane ;
reconsider Q = T2_to_BK P as Element of BK_model ;
consider p being Element of BK_model such that
A4: Q9 = p and
A5: BK_to_T2 Q9 = BK_to_REAL2 p by Def01;
consider v being non zero Element of (TOP-REAL 3) such that
A6: Dir v = p and
A7: v . 3 = 1 and
A8: BK_to_REAL2 p = |[(v . 1),(v . 2)]| by BKMODEL2:def 2;
are_Prop u,v by A4, A6, A1, ANPROJ_1:22;
then consider a being Real such that
a <> 0 and
A9: u = a * v by ANPROJ_1:1;
A10: 1 = a * (v `3) by A2, A9, EUCLID_5:9
.= a * 1 by A7, EUCLID_5:def 3
.= a ;
|[(u `1),(u `2),(u `3)]| = u by EUCLID_5:3
.= |[(1 * (v `1)),(1 * (v `2)),(1 * (v `3))]| by A9, A10, EUCLID_5:7 ;
then ( u `1 = v `1 & u `2 = v `2 ) by FINSEQ_1:78;
then ( u `1 = v . 1 & u `2 = v . 2 ) by EUCLID_5:def 1, EUCLID_5:def 2;
hence BK_to_T2 (T2_to_BK P) = P by A5, A8, A3; :: thesis: verum