Algebra 2/Ellipses

In the previous lesson we studied parabolas, which arise from slicing a cone parallel to the cone edge. We saw that it had a much more useful representation in terms of points equidistant from a point and a line.

Here we study ellipses, which arise from slicing a cone at a different angle. If the slice forms an acute angle with the axis of symmetry, which is greater than the angle formed by the cone edge, then the result is an ellipse.

But as before, this description is hard to work with. Luckily, there is a proof which shows that ellipses can be re-characterized in terms of distances, just like for parabolas!

The proof of this is challenging, but the excellent math YouTube channel 3 Brown 1 Blue provides an inspiring presentation of it: 3B1B - Why slicing a cone gives an ellipse (beautiful proof).

We will simply take the result for granted here:

Let ${\displaystyle F_{1},F_{2}}$  be any two points, and let d be any positive real number.  Then the locus of points, P, such that the sum of distances to ${\displaystyle F_{1}}$  and ${\displaystyle F_{2}}$  equals d, is an ellipse.  

There is a fun alternate characterization of the same idea -- a little do-it-yourself craft that you can even share with small kids, which is always fun!

1. Take a length of string. This will represent d, the total length.
2. Take two pins and a piece of paper, and pin the string into the paper at two points. Make sure that you don't mind pressing a pin into whatever is underneath the paper! The pins will represent the two focal points, ${\displaystyle F_{1}}$  and ${\displaystyle F_{2}}$ .
3. Take a pencil and place it against the string, using the pencil to pull the string firmly but without pulling out the pins.
4. Place the pencil to the paper, and then sweep out a curve on the paper, always keeping the string and pencil tight.

The result is an ellipse!

We call each point ${\displaystyle F_{1},F_{2}}$  a "focus", the Latin plural of which is "focii".

To begin with, for simplicity, we will assume that ${\displaystyle F_{1}(-c,0)}$  and ${\displaystyle F_{2}(c,0)}$ , for a positive c. Which is to say, the focii are placed on the x-axis at equal distances to the left and right.

We call ${\displaystyle V_{l},V_{r},V_{u},V_{d}}$  the vertices, which are the the left-most, right-most, up-most, and down-most points on the ellipse. In the diagram on the right, these are labeled A, B, C, D.

Because we place the focii on the x-axis, it is clear from the diagram that there are positive numbers a, b such that ${\displaystyle V_{l}(-a,0),V_{r}(a,0),V_{u}(0,b),V(0,-b)}$ , respectively.

Let ${\displaystyle P(x,y)}$  be any point on the ellipse.

We now seek an equation which defines the relationship between x, y, and the parameters a, b, c, d.

First notice that if we set P to ${\displaystyle V_{r}}$  we can see that d must equal ${\displaystyle F_{1}V_{r}+F_{2}V_{r}}$ .

But ${\displaystyle F_{1}V=c+a}$  and ${\displaystyle F_{2}V=a-c}$ . Therefore we obtain a first useful equation

${\displaystyle \color {red}d=2a}$ 

Next consider ${\displaystyle V_{u}}$  which must also satisfy ${\displaystyle d=F_{1}V_{u}+F_{2}V_{u}}$ .

But notice that the corresponding edges now form an isosceles triangle and therefore ${\displaystyle F_{1}V={\frac {f}{2}}=a}$  and ${\displaystyle F_{2}V=a}$ .

Then if we consider the right triangle formed by the origin and ${\displaystyle F_{2}}$  and ${\displaystyle V_{u}}$ , it has legs c and b, and hypotenuse a.