Question: If the diagonals AC and BD of a quadrilateral ABCD intersect at some point E, prove that the vertices A,B,C,and D must all lie in the same plane. Assume the incidence axioms are valid.
Attempt and possible solution: I started working on this problem by looking at the definition of quadrilateral.
By definition quadrilateral " It is the set of all points on segments AB,BC,CD,and DA such that no three vertices A,B,C, and D are collinear and no two sides meet except at end points. "
Let segments AC and BC be diagonals of the quadrilateral ABCD, they intersect at E.
By the definition of quadrilateral let A, B, C lies in a same plane and they don't lie on a same line (non-collinear).
Suppose D does not lie on the same plane as A,B, and C.
But D must be adjacent to A and C.
Now consider the plane containing the line joining AD and CD.
Join the other diagonal BD.
Now BD is a line intersecting the plane containing A, B and C at B.
Also BD lies on the plane other than A,B, and C. So BD can not intersect the other diagonal at any point E other than B.
But B is not a point on the diagonal AC.
That is a contradiction to our hypothesis.
Therefore we can conclude A,B,C, and D must lie on the same plane.
