X^2 = 4ay
X^2 = 4y therefore a = 1
Let P(2ap,ap^2) = P(2p,p^2) and Q(2q,q^2) (p>0, q<0)
Show eqn of tangent at P is y = px – p^2
Show eqn of tangent at Q is y = qx – q^2
Solve simultaneously to show T(p+q , pq)
Show eqn of normal of normal at P is y – p^2 = -(1/p)(x – 2p)
Show eqn of normal of normal at P is y = -x/p + 2 + p^2
Solve simultaneously with y = (x^2)/4
To get px^2 + 4x -8p – 4p^3 = 0
Use quadratic formula to show
x = 2p (which is abscissa of P) or x= (-4 – 2p^2)/p (which is abscissa of Q)
Using y = x^2/4 ShowQ( (-4 – 2p^2)/p , ((2 + p^2)^2)/(p^2) )
Given QS = 2PS
Then QS^2 = 4PS^2
Some painful distance formulas squared and put LHS over a common denominator of p^4
Then multlipy both sides by p^4
Arrives at
p^8 + 10p^6 + 33p^4 + 40p^2 + 16 = 4p^8 + 8p^6 + 4p^4
0 = 3p^8 – 2p^6 – 29p^4 – 40p^2 – 16
try p= 2 (LHS = RHS) therefore p = 2 (due to the nature of the signs of the coefficients & the powers all being even you can argue that no other positive solution for p exists)
therefore P(4 ,4) & Q(-6 , 9) hence q is -3
Consider grad PS X grad QS
= ((4-1)/4) X ((9-1)/-6)
= -1
Therefore PS perpendicular to QS (Part (i) QED)
Sub p = 2 & q = -3 into T((p + q) , pq) then T(-1 , -6)
PQ = SQRT((4 - -6)^2 + (4 – 9)^2) = SQRT(125)
PT = SQRT((4 - -1)^2 + (4 - -6)^2) = SQRT(125)
Therefore PQ = PT (both = SQRT(125)) (Part (ii) QED)
I will be checking back to this thread to see if others come up with a much simplier solution.
