let F be Field; :: thesis:
let S be SymSp of F; :: thesis:
let b, a, x, y be Element of S; :: thesis:
set 0F = 0. F;
assume that
A1: (1_ F) + (1_ F) <> 0. F and
A2: not a _|_ ; :: thesis:
A3: a <> 0. S by A2, Th11, Th12;
A4: ( PProJ a,b,x,y = 0. F implies x _|_ )

proof

assume A5: PProJ a,b,x,y = 0. F ; :: thesis:

A6: now

given p being Element of S such that A7: not a _|_ and
A8: not x _|_ ; :: thesis:

A9: now

assume A10: ProJ p,a,x = 0. F ; :: thesis:
not p _|_ by A7, Th12;
then p _|_ by A10, Th36;
hence contradiction by A8, Th12; :: thesis:

end;

((ProJ a,b,p) * (ProJ p,a,x)) * (ProJ x,p,y) = 0. F by A1, A2, A5, A7, A8, Def6;
then ( (ProJ a,b,p) * (ProJ p,a,x) = 0. F or ProJ x,p,y = 0. F ) by VECTSP_1:44;
then ( ProJ a,b,p = 0. F or ProJ p,a,x = 0. F or ProJ x,p,y = 0. F ) by VECTSP_1:44;
hence x _|_ by A2, A7, A8, A9, Th36; :: thesis:

end;

now

assume for p being Element of S holds
( a _|_ or x _|_ ) ; :: thesis:
then x = 0. S by A3, Th21;
hence x _|_ by Th11, Th12; :: thesis:

end;

hence x _|_ by A6; :: thesis:

end;

( x _|_ implies PProJ a,b,x,y = 0. F )

proof

assume A11: x _|_ ; :: thesis:

A12: now

assume x <> 0. S ; :: thesis:
then consider p being Element of S such that
A13: not a _|_ and
A14: not x _|_ by A3, Th21;
ProJ x,p,y = 0. F by A11, A14, Th36;
then ((ProJ a,b,p) * (ProJ p,a,x)) * (ProJ x,p,y) = 0. F by VECTSP_1:39;
hence PProJ a,b,x,y = 0. F by A1, A2, A13, A14, Def6; :: thesis:

end;

now

assume x = 0. S ; :: thesis:
then for p being Element of S holds
( a _|_ or x _|_ ) by Th11, Th12;
hence PProJ a,b,x,y = 0. F by A1, A2, Def6; :: thesis:

end;

hence PProJ a,b,x,y = 0. F by A12; :: thesis:

end;

hence ( PProJ a,b,x,y = 0. F iff x _|_ ) by A4; :: thesis: