10.1 In the diagram, \( \triangle ABC \) and \( \triangle ADEF \) are drawn such that \( \angle A = \angle D \), \angle B = \angle E \) and \( \angle C = \angle F \) - NSC Mathematics - Question 10 - 2022 - Paper 2

To prove that ( FB \parallel CG ), we notice that ( BF \perp EC ) and ( EC ) is tangent to the circle at ( C ). By the tangent-secant theorem, this means that angles ( \angle FBC ) and ( \angle EGC ) are equal. Therefore, by the alternate interior angles theorem, since these angles are equal, we can conclude that ( FB \parallel CG ).

To prove that ( AFCB \parallel ACDB ), notice that angles ( \angle CFB ) and ( \angle CDA ) are both equal since they subtend the same arc ( AB ) in both triangles. By the Converse of the Alternate Angle Theorem, we can conclude that the lines are parallel, thus ( AFCB \parallel ACDB ).

We find that ( G ) is the midpoint of ( AD ) and by the properties of a circle, ( OC ) bisects the angle, ensuring ( \angle GCO = 90^{\circ} ). Since ( OC ) is a radius and bisects the chord at its midpoint, we conclude that ( \hat{G} = 90° ).

Using the property of circles, in ( \triangle CDB ), we apply the Power of a Point theorem which states that the product of the lengths from a point outside the circle to points on the circle is constant. Therefore, we have: [ CD^2 = CG \cdot DB. ]

From the earlier established relation ( CD^2 = CG \cdot DB ), we rearrange to express ( DB ) in terms of ( CG ) and observe that by geometry of the diagram and properties of the tangent segments, we have that: [ DB = CG + FB. ] This concludes the proof.