Given is: ..a point P on the directrix of a parabola with foci $F$.
What I want to show is: the tangents of a parabola given by $y=kx^2$ through $P = (x_0, y_0)$ are orthogonal and the line between the points, where the tangents touch the parabola, contains the foci F.
What I have done is:
I need a tangent through $P$ that touches the parabola in $B = (a, ka^2)$. So I have $m = \frac{\delta x}{\delta y}=\frac{ka^2-y_0}{a-x_0} \rightarrow ka^2-y_0 =m(a-x_0).$
However, with the first derivate of the parabola I get: $y' = 2ka$ and therefore $m = 2ka \rightarrow a = \frac{m}{2k}$.
From 1 and 2 I get: $k\cdot \frac{m^2}{4k^2} -y_0 = m\cdot (\frac{m}{2k} - x_0)$. And after some steps: $0 = m^2 - 4kmx_0 + 4ky_0$.
So because $y_0 < kx_0^2$ (because $P$ is external to the parabola!) I should get two solutions for this quadratic equation, which means 2 possible values $m_1, m_2$.
$m_1 = 2(kx_0 - \sqrt{x_0^2 k^2 -ky_0})$ and $m_2 = 2(kx_0 +\sqrt{x_0^2 k^2 -ky_0})$.
Finally I have $m_1 \cdot m_2 = 4ky_0 = -1 \leftrightarrow y_0 = \frac{-1}{4k}$ or in words: $P$ must be on the directrix! So if the tangents are orthogonal, P must be on the directrix. This should be enough for the first step?
I now have to show that the line, that contains the 'touching points' $B = (a, ka^2)$ and a second points $C = (c, kc^2 )$ also contains the foci $F$. How can I now show this?
Many thanks for any hints and solutions (or corrections) :)
