Algebra 2/Parabolas

In Terms of Distances[edit | edit source]

Although we define the parabola as an intersection of a cone and plane parallel to the edge of the cone, this is pretty clearly a difficult definition to work with.

But luckily it turns out that there is a proof (due to Dandeline, which can be found in a nice presentation here: Dandeline's proof) that a parabola is equivalently defined as the locus of points equally distant between some point and some line.

More precisely, we begin with a point which we call the focus, and a line which we call the directrix. In principle these may be any point and line which are not coincident.

For simplicity we will assume (until indicated otherwise) that the focus has horizontal coordinate equal to 0. This will make calculations simpler. The only thing left unknown about the focus, then, is its vertical coordinate.

We will write the focus as $F(0,c)$ .

Also for simplicity we assume that the directrix is horizontal. Therefore the directrix always has the form

y=a

where

a\neq c

We also define the vertex to be the point which is equally distant from the focus to the line. This makes the vertex either the minimum point (if the directrix is below the focus) or the maximum point (if the directrix is above).

Exercise 1. Find the vertex.

Suppose the focus is $F(0,2)$ and the directrix is $y=-2$ . Find the vertex.

Solution

The diagram to the right shows essentially this situation, although coordinates are not shown explicitly.

Still, if the focus is $F(0,2)$ and the vertex is visibly straight down from this by a distance of 2, then the vertex is $V(0,0)$ .

Exercise 2. Tilt your head and find the vertex

We will primarily consider parabolas for which the directrix is horizontal. In this case we often say that the resulting parabola "opens vertically".

However, once you understand parabolas which open vertically, it is not very hard to understand ones which open horizontally (and have a directrix which is vertical).

Suppose the focus is $F(0,0)$ and the directrix is $x=1$ . Find the vertex.

Solution

As with most things in algebra and geometry, your first instinct should always be to draw a picture to help understand the problem. I've drawn the picture to the right.

As always with parabolas, the vertex is just precisely half-way between the focus and directrix.

In this case, it is V(1/2, 0).

In general, a point $P(x,y)$ is on the parabola if and only if the distance FP equals the distance from P to the directrix.

Because F(0,c) then the distance FP is given by the distance formula,

d_{f}={\sqrt {(x-0)^{2}+(y-c)^{2}}}

Because the directrix is horizontal, it is easy to find the distance to P.

d_{d}=|y-a|

By definition of a parabola, being points at which these two distances are equal, then

d_{f}=d_{d}

We define p to be the distance from the vertex to the focus and therefore, trivially, it is always half the distance from the focus to the directrix. It can always be computed by

p=|c-a|/2

If we write the coordinates of the vertex as $V(h,k)$ then clearly $h=0$ because the focus, too, has its horizontal coordinate at 0. Also, if we assume $c>a$ then

k=c-p=a+p

If on the other hand $c<a$ then $k=c+p=a-p$ .

Exercise 3. Derive the Parabola Formula

From the setup described above, derive the equation

4p(y-k)=x^{2}

.

Hint: Write out the equation $d_{f}=d_{d}$ using what you know about each of these. Then square both sides to get rid of the square-root. Then distribute out all operations until you're able to solve for $x^{2}$ .

Solution

d_{f}^{2}=x^{2}+(y-c)^{2}=x^{2}+y^{2}-2cy+c^{2}

and

d_{d}^{2}=(y-a)^{2}=y^{2}-2ay+a^{2}

so setting these equal, we can cancel the $y^{2}$ on each side,

x^{2}-2cy+c^{2}=a^{2}-2ay

Solving for $x^{2}$ we get

x^{2}=2y(c-a)+a^{2}-c^{2}

which, by the difference of squares, is

x^{2}=2y(c-a)+(a+c)(a-c)

Recalling that $c-a=2p$ and $a+c=2k$ then we get

x^{2}=4py+(2p)(-2k)

The right-hand side is $4py-4kp$ . If we factor the $4p$ then we're done.

x^{2}=4p(y-k)

□

Exercise 4. Now a full pass through

Suppose the focus is at $F(0,2)$ and the directrix is $y=-2$ .

Find all other information. The full set of information in any parabola problem is: the values of $a,c,p,h,k$ , the coordinates of the vertex, the equation of the directrix, and the equation of the parabola.

Solution

Since $F(0,2)$ then we are given c=2. Since the directrix is $y=-2$ then we are given $a=-2$ . Since there is no horizontal translation $h=0$ .

k={\frac {a+c}{2}}={\frac {-2+2}{2}}=0

p={\frac {c-a}{2}}={\frac {2-(-2)}{2}}=2

With these values known we can state the locations of all points.

F(0,2),V(0,0)

The directrix was given as $y=-2$ .

Finally, the equation of the parabola is $4\cdot 2(y-0)=x^{2}$ which simplifies to

8y=x^{2}

Exercise 5. Horizontal translation

Let's consider what happens when the focus does not have its horizontal coordinate at 0. (It will turn out: not much.)

Suppose the focus is at $F(-2,10)$ and the directrix at $y=4$ . Find the equation of the parabola determined by these.

Solution

We find many of the relevant quantities the same way as before. We have

c=10

and

a=4

so

k={\frac {a+c}{2}}={\frac {4+10}{2}}=7

. Also

p={\frac {c-a}{2}}={\frac {10-4}{2}}=3

. The equation would usually be

4\cdot 3(y-7)=x^{2}

which is

12(y-7)=x^{2}

This problem is no different except that, because the focus is translated 2 to the left, then the relation is translated 2 to the left.

We've seen earlier that to translate the relation $R(x,y)$ by $\langle i,j\rangle$ , it is represented by $R(x-i,y-j)$ . Here we translate by $\langle -2,0\rangle$ .

Therefore the equation of this translation is $12(y-7)=(x-(-2))^{2}$ , which is

12(y-7)=(x+2)^{2}

The General Equation: Opens Upward[edit | edit source]

The above is a demonstration that the equation for a parabola which opens upward is

4p(y-k)=(x-h)^{2}

As before, the equations $k={\frac {a+c}{2}}$ and $p={\frac {c-a}{2}}$ .

a is the position of the directrix, $F(h,c)$ the coordinates of the focus, $V(h,k)$ the coordinates of the vertex, and p the distance from vertex to focus.

Exercise 6. From the equation, everything

In this exercise we will see that if we know the equation of a parabola, then we can recover all of the information: $a,c,p,h,k$ .

This means that if you know how to find the equation, then you know how to find everything.

Suppose a parabola has equation ${\frac {1}{4}}(y+1)=(x-1)^{2}$ . Find the parameters $a,c,p,h,k$ .

Solution

Since the general formula is $4p(y-k)=(x-h)^{2}$ then we can read off $h=1,k=-1$ . We can see $4p={\frac {1}{4}}$ so that $p={\frac {1}{16}}$ .

Then $k={\frac {a+c}{2}}$ gives $-1={\frac {a+c}{2}}$ . Also $p={\frac {c-a}{2}}$ gives ${\frac {1}{16}}={\frac {c-a}{2}}$ . This produces the system of equations

{\begin{aligned}-2&=c+a\\{\frac {1}{8}}&=c-a\end{aligned}}

Summing the equations gives $-{\frac {15}{8}}=2c$ and therefore $c=-{\frac {15}{16}}$ . Therefore

{\frac {1}{8}}=\left(-{\frac {15}{16}}\right)-a

which entails $a={\frac {17}{16}}$ .

Now every parameter has been determined.

The General Equations: Downward, Rightward, Leftward[edit | edit source]

Until now we've assumed the directrix is horizontal, and the focus is above the directrix. This causes the parabola to open upward.

If the focus is below the directrix, all the same analysis applies. You will find that the only thing which changes is

p=-{\frac {c-a}{2}}

which is necessary so that p is positive. This is necessary because p is a distance and so must be positive.

Then downstream of that, we get an equation which is only slightly different.

-4p(y-k)=(x-h)^{2}

Exercise 7. Downward Parabola

Suppose the vertex of a parabola is at $V(1,2)$ and the focus is at $F(1,0)$ . Determine the equation of the parabola.

Solution

It's given that $h=1$ and $k=2$ , and $c=0$ . Then $k={\frac {a+c}{2}}$ gives

2={\frac {a+0}{2}}

so $a=4$ . Also $p=-{\frac {c-a}{2}}$ gives

p=-{\frac {0-4}{2}}=2

Then the equation of the parabola is $4\cdot 2(y-2)=(x-1)^{2}$ which is

8(y-2)=(x-1)^{2}

Next consider if the directrix is vertical rather than horizontal. Now the vertex and focus will share the same vertical coordinate by may have different horizontal coordinates. We now say that $F(b,k)$ and $V(h,k)$ are the coordinates of the focus and vertex, and as before p is the distance from focus to vertex.

Much like before,

h={\frac {a+b}{2}}

If the focus is to the right of the directrix, the equations become

p={\frac {b-a}{2}}

and the equation becomes

4p(x-h)=(y-k)^{2}

If the focus is left of the directrix,

p=-{\frac {b-a}{2}}

and the equation becomes

-4p(x-h)=(y-k)^{2}

A consolidated display of the four cases is shown below.

vertical, horizontal / focus greater, lesser
Opens	Focus greater	Focus lesser
vertical	${\begin{aligned}{\color {red}k={\frac {a+c}{2}}},&\quad \color {blue}p={\frac {c-a}{2}}\\4p(y-k)&=(x-h)^{2}\end{aligned}}$	${\begin{aligned}{\color {red}k={\frac {a+c}{2}}},&\quad \color {blue}p=-{\frac {c-a}{2}}\\-4p(y-k)&=(x-h)^{2}\end{aligned}}$
horizontal	${\begin{aligned}{\color {red}h={\frac {a+b}{2}}},&\quad \color {blue}p={\frac {b-a}{2}}\\4p(x-h)&=(y-k)^{2}\end{aligned}}$	${\begin{aligned}{\color {red}k={\frac {a+b}{2}}},&\quad \color {blue}p=-{\frac {b-a}{2}}\\-4p(x-h)&=(y-k)^{2}\end{aligned}}$

Exercise 8. Parabolic dish

A satellite dish is in the shape of a parabola, as shown.

It turns out that, if a light ray comes into the dish and strikes the surface, it will always reflect off of the surface and be directed into the focus. This is shown on the left.

Assume that the rim of the dish has a diameter of 20 feet. Also assume that the depth of the dish is 10 feet.

Find the point at where all of the incoming rays will intersect.

Solution

In effect we need to find the distance from the the vertex to the focus. The focus is the point where the rays intersect, and the vertex is the "bottom" of the depth of the parabola.

It shouldn't matter where we place the satellite in our coordinate space, so just for simplicity, let's set the vertex at (0,0) and have the parabola open upward. So $h=0,k=0$ . Then the equation is

4py=x^{2}

Because of this choice of coordinate system, the right edge of the rim is 10 feet to the right on the x axis, and 10 feet above the axis. That is to say, it passes through the point $(10,10)$ .