1) Obtain the equation of the tangent $P(a\cos\phi, b\sin \phi)$ on the ellipse $\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$.
2) If the tangent at P meets the axes at $TT^\prime$ and the diameter through P meets the ellipse again at $P^\prime$. Show that $$\tan TP^\prime T^\prime=\frac{2OT\cdot OT^\prime}{a^2+b^2+OP^2}$$
My attempt: Equation of tangent to an ellipse: $$\frac{xx_1}{a^2}+\frac{yy_1}{b^2}=1\quad\\\frac{x\cos\phi}{a}+\frac{y\sin\phi}{b}=1 \quad \color{red}{P(a\cos\phi, b\sin\phi) }$$ I have a serious challenge with the second part of the question I made the following deductions from the diagram: ${TT^\prime}^2={OT'}^2+{OT}^2\\PP'=OP+OP'\\$ I also considered finding the angles between lines $P'T $ and $P'T'$ but don't seem to be making any headway. Any hint on how this can be done?
