let V be RealLinearSpace; :: thesis: for x, y being VECTOR of V st Gen x,y holds
ex u, v, w being VECTOR of V st
( u,v,u,w are_COrtm_wrt x,y & ( for v1, w1 being VECTOR of V holds
( not v1,w1,u,v are_COrtm_wrt x,y or ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) ) )
let x, y be VECTOR of V; :: thesis: ( Gen x,y implies ex u, v, w being VECTOR of V st
( u,v,u,w are_COrtm_wrt x,y & ( for v1, w1 being VECTOR of V holds
( not v1,w1,u,v are_COrtm_wrt x,y or ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) ) ) )
assume A1: Gen x,y ; :: thesis: ex u, v, w being VECTOR of V st
( u,v,u,w are_COrtm_wrt x,y & ( for v1, w1 being VECTOR of V holds
( not v1,w1,u,v are_COrtm_wrt x,y or ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) ) )
take u = (0 * x) + (0 * y); :: thesis: ex v, w being VECTOR of V st
( u,v,u,w are_COrtm_wrt x,y & ( for v1, w1 being VECTOR of V holds
( not v1,w1,u,v are_COrtm_wrt x,y or ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) ) )
take v = (1 * x) + (1 * y); :: thesis: ex w being VECTOR of V st
( u,v,u,w are_COrtm_wrt x,y & ( for v1, w1 being VECTOR of V holds
( not v1,w1,u,v are_COrtm_wrt x,y or ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) ) )
take w = (1 * x) + ((- 1) * y); :: thesis: ( u,v,u,w are_COrtm_wrt x,y & ( for v1, w1 being VECTOR of V holds
( not v1,w1,u,v are_COrtm_wrt x,y or ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) ) )
( pr1 x,y,u = 0 & pr2 x,y,u = 0 & pr1 x,y,v = 1 & pr2 x,y,v = 1 ) by A1, Lm6;
then A2: Ortm x,y,u, Ortm x,y,v // u,w by ANALOAF:17;
for v1, w1 being VECTOR of V holds
( not v1,w1,u,v are_COrtm_wrt x,y or ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 )
proof
let v1, w1 be VECTOR of V; :: thesis: ( not v1,w1,u,v are_COrtm_wrt x,y or ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 )
assume v1,w1,u,v are_COrtm_wrt x,y ; :: thesis: ( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 )
then A3: Ortm x,y,v1, Ortm x,y,w1 // u,v by Def4;
now
assume A4: v1 <> w1 ; :: thesis: ( ( v1,w1,u,w are_COrtm_wrt x,y or v1,w1,w,u are_COrtm_wrt x,y ) implies ex a, b being Real st
( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) )
assume ( v1,w1,u,w are_COrtm_wrt x,y or v1,w1,w,u are_COrtm_wrt x,y ) ; :: thesis: ex a, b being Real st
( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 )
then ( Ortm x,y,v1, Ortm x,y,w1 // u,w or Ortm x,y,v1, Ortm x,y,w1 // w,u ) by Def4;
then ( u,v // u,w or u,v // w,u ) by A1, A3, A4, Th6, ANALOAF:20;
then consider a, b being Real such that
A5: ( a * (v - u) = b * (w - u) & ( a <> 0 or b <> 0 ) ) by ANALMETR:18;
take a = a; :: thesis: ex b being Real st
( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 )
take b = b; :: thesis: ( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 )
u = (0. V) + (0 * y) by RLVECT_1:23
.= (0. V) + (0. V) by RLVECT_1:23
.= 0. V by RLVECT_1:10 ;
then ( a * v = b * (w - (0. V)) & ( a <> 0 or b <> 0 ) ) by A5, RLVECT_1:26;
then A6: ( a * v = b * w & ( a <> 0 or b <> 0 ) ) by RLVECT_1:26;
A7: now
assume A8: a <> 0 ; :: thesis: ( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 )
((a " ) * a) * v = (a " ) * (b * w) by A6, RLVECT_1:def 9;
then ((a " ) * a) * v = ((a " ) * b) * w by RLVECT_1:def 9;
then 1 * v = ((a " ) * b) * w by A8, XCMPLX_0:def 7;
then 1 * v = ((((a " ) * b) * 1) * x) + ((((a " ) * b) * (- 1)) * y) by Lm2;
then ((1 * 1) * x) + ((1 * 1) * y) = ((((a " ) * b) * 1) * x) + ((((a " ) * b) * (- 1)) * y) by Lm2;
then ( a * 1 = a * ((a " ) * (b * 1)) & 1 = ((a " ) * b) * (- 1) ) by A1, Lm3;
then ( a * 1 = (a * (a " )) * (b * 1) & 1 = ((a " ) * b) * (- 1) ) ;
then 1 = ((a " ) * a) * (- 1) by A8, XCMPLX_0:def 7;
hence ( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) by A8, XCMPLX_0:def 7; :: thesis: verum
end;
now
assume A9: b <> 0 ; :: thesis: ( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 )
((b " ) * a) * v = (b " ) * (b * w) by A6, RLVECT_1:def 9;
then ((b " ) * a) * v = ((b " ) * b) * w by RLVECT_1:def 9;
then ((b " ) * a) * v = 1 * w by A9, XCMPLX_0:def 7;
then ((((b " ) * a) * 1) * x) + ((((b " ) * a) * 1) * y) = 1 * w by Lm2;
then ((((b " ) * a) * 1) * x) + ((((b " ) * a) * 1) * y) = ((1 * 1) * x) + ((1 * (- 1)) * y) by Lm2;
then ( b * 1 = b * ((b " ) * (a * 1)) & - 1 = ((b " ) * a) * 1 ) by A1, Lm3;
then ( b * 1 = (b * (b " )) * (a * 1) & - 1 = ((b " ) * a) * 1 ) ;
then - 1 = ((b " ) * b) * 1 by A9, XCMPLX_0:def 7;
hence ( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) by A9, XCMPLX_0:def 7; :: thesis: verum
end;
hence ( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) by A5, A7; :: thesis: verum
end;
hence ( ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) ; :: thesis: verum
end;
hence ( u,v,u,w are_COrtm_wrt x,y & ( for v1, w1 being VECTOR of V holds
( not v1,w1,u,v are_COrtm_wrt x,y or ( not v1,w1,u,w are_COrtm_wrt x,y & not v1,w1,w,u are_COrtm_wrt x,y ) or v1 = w1 ) ) ) by A2, Def4; :: thesis: verum