The line `x - b +lambda y = 0` cuts the parabola `y^(2) = 4ax (a gt 0)` at `P(t_(1))` and `Q(t_(2))`. If `b in [2a, 4a]` then range of `t_(1)t_(2)` where `lambda in R` is

If the tangents at t_(1) and t_(2) on y^(2) = 4ax are at right angles if

If the tangents at t_(1) and t_(2) on y^(2) =4ax meet on the directrix then

The tangents to the parabola y^2=4ax at P(at_1^2,2at_1) , and Q(at_2^2,2at_2) , intersect at R. Prove that the area of the triangle PQR is 1/2a^2(t_1-t_2)^3

If the normal at t_(1) on the parabola y^(2)=4ax meet it again at t_(2) on the curve then t_(1)(t_(1)+t_(2))+2 = ?

If the tangents at t_(1) and t_(2) on y^(2) = 4ax makes complimentary angles with axis then t_(1)t_(2) =

Let A, B and C be three points taken on the parabola y^(2)=4ax with coordinates (at_(i)^(2), 2at_(i)), i=1, 2, 3, where t_(1), t_(2)" and "t_(3) are in A.P. If AA', BB' and CC' are focal chords and coordinates of A', B' and C' are (at'_(i)^(2), 2at'_(i)),i=1, 2, 3, them t'_(1), t'_(2)and t'_(3) are in

If the normal to the parabola y^2=4a x at point t_1 cuts the parabola again at point t_2 , then prove that (t_2)^2geq8.

If the normal at (1,2) on the parabola y^(2)=4x meets the parabola again at the point (t^(2),2t) then the value of t is

If the normal at(1, 2) on the parabola y^(2)=4x meets the parabola again at the point (t^(2), 2t) then the value of t, is

Let normals to the parabola y^(2)=4x at variable points P(t_(1)^(2), 2t_(1)) and Q(t_(2)^(2), 2t_(2)) meet at the point R(t^(2) 2t) , then the line joining P and Q always passes through a fixed point (alpha, beta) , then the value of |alpha+beta| is equal to