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Mathematics-Online course: Preparatory Course Mathematics - Linear Algebra and Geometry - Quadratic Curves

Ellipse


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For the points $ P=(x,y)$ on an ellipse the sum of the distances from two fixed points $ F_{\pm}$ (the foci) is a given positive constant:

$\displaystyle \vert\overrightarrow{PF_-}\vert + \vert\overrightarrow{PF_+}\vert
= 2 a
$

with $ 2a>\vert\overrightarrow{F_-F_+}\vert$ .

\includegraphics[width=12.4cm]{a_ellipse}

If $ F_{\pm}=(\pm f,0)$ , then we have for the coordinates

$\displaystyle \frac{x^2}{a^2} + \frac{y^2}{b^2} = 1,\quad
b^2 = a^2 - f^2\,
,
$

and

$\displaystyle r^2 = \frac{b^2}{1-(f/a)^2\cos^2(\varphi)}
$

for the polar coordinates of the points $ P$ .

A parameterisation of the ellipse is given by

$\displaystyle x=a\cos t,\quad y=b\sin t
$

with $ t\in [0,2\pi)$ .


Equivalence of the representations follows immediatly by calculation.

To proof

$\displaystyle \vert\overrightarrow{PF_-}\vert + \vert\overrightarrow{PF_+}\vert...
...{\displaystyle{\frac{x^2}{a^2} + \frac{y^2}{b^2} = 1}},\quad
b^2 = a^2 - f^2
$

by squaring of

$\displaystyle \underbrace{2a - \sqrt{(x+f)^2 + y^2}}_{> 0} =
\sqrt{(x-f)^2 + y^2}
$

we obtain the equivalent equation

$\displaystyle \underbrace{4a^2 + 4xf}_{>0} =
4a \sqrt{(x+f)^2 + y^2}\,
.
$

Squaring again and dividing by $ 4a$ yield

$\displaystyle a^2 + 2xf + \frac{f^2}{a^2} x^2 =
x^2 + 2xf + f^2 + y^2\,
.
$

Substituting $ f^2 = a^2-b^2$ and transforming we obtain the coordinate form.

To proof

$\displaystyle r^2 = \frac{b^2}{1-(f/a)^2\cos^2(\varphi)}
$

we multiply by the denominator and take into account that

$\displaystyle x^2 = (x^2 + y^2)\cos^2(\varphi)\,
.
$

This implies

$\displaystyle x^2 + y^2 - \frac{a^2-b^2}{a^2} x^2 = b^2
$

and division by $ b^2$ yields the coordinate form.


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  automatically generated 1/9/2017