 reserve x,y for object, X,Y,Z for set;
 reserve GF for commutative
     Abelian add-associative right_zeroed right_complementable
     associative well-unital distributive non empty doubleLoopStr;
 reserve a,b for Element of GF;
 reserve V for scalar-distributive vector-distributive
   scalar-associative scalar-unital add-associative right_zeroed
     right_complementable Abelian non empty ModuleStr over GF;
 reserve v,v1,v2,u for Vector of V;
 reserve A,B,C for Subset of V;
 reserve T for finite Subset of V;
 reserve l for Linear_Combination of A;
 reserve f,g for Function of V, GF;
 reserve GF for commutative non degenerated almost_left_invertible
     Abelian add-associative right_zeroed right_complementable
     associative well-unital distributive non empty doubleLoopStr;
 reserve a,b for Element of GF;
 reserve V for scalar-distributive vector-distributive
   scalar-associative scalar-unital add-associative right_zeroed
     right_complementable Abelian non empty ModuleStr over GF;
 reserve v,v1,v2,u for Vector of V;
 reserve A,B,C for Subset of V;
 reserve T for finite Subset of V;
 reserve l for Linear_Combination of A;
 reserve f,g for Function of V, GF;
reserve l0 for Linear_Combination of {}(the carrier of V);
reserve x for set,
  R for Ring,
  V for LeftMod of R,
  v,v1,v2 for Vector of V,
  A, B for Subset of V;

theorem 
  for R being non degenerated Ring,
      V being LeftMod of R,
      v1, v2 being Vector of V holds
  {v1,v2} is linearly-independent implies v1 <> 0.V & v2 <> 0.V
proof
  let R be non degenerated Ring,
      V be LeftMod of R,
      v1, v2 be Vector of V;
A1: v1 in {v1,v2} & v2 in {v1,v2} by TARSKI:def 2;
  assume {v1,v2} is linearly-independent;
  hence thesis by A1,Th2;
end;
