Equations of Ellipses Practice

1. Write an equation for an ellipse centered at the origin, which has foci at ‍$(\pm5,0)$ and vertices at ‍‍$(\pm\sqrt{41},0)$.

2. Write an equation for an ellipse centered at the origin, which has foci at ‍$(\pm\sqrt{13},0)$ and co-vertices at ‍‍$(0,\pm11)$.

3. Write an equation for an ellipse centered at the origin, which has foci at ‍$(\pm8,0)$ and vertices at ‍‍$(\pm17,0)$.

4. Write an equation for an ellipse centered at the origin, which has foci at ‍$(\pm\sqrt{8},0)$ and co-vertices at ‍‍$(0,\pm\sqrt{10})$.

Source: Khan Academy, https://www.khanacademy.org/math/precalculus/x9e81a4f98389efdf:conics/x9e81a4f98389efdf:ellipse-foci/e/equation-of-ellipse-from-foci
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 3.0 License.

1. The strategy
   

   In order to find the equation of the ellipse, we perform the following steps.
   

   1. Find the focal length, $f$, and the major radius,‍ $p$, using the given information about the center, the foci, and the vertices.

   2. Find the minor radius, $q$, using the equation $f^2=p^2-q^2$.

   3. Match the major and minor radii to the vertical and horizontal radii by determining the axis along which the foci lie.

   4. Substitute all the values we found in the standard equation of an ellipse.

   Finding the focal length and major radius
   

   The focal length is $5$ units, since the foci are at ‍$(\pm 5,0)$.

   The major radius is $\sqrt{41}$ units, since the vertices are at ‍$(\pm \sqrt{41},0)$.

   Finding the minor radius

   We've found that the focal length, $f$, is ‍$5$ units, and the major radius, ‍$p$, is ‍$\sqrt{41}$ units. Let's substitute these values into the equation to find the minor radius, $q$.

   $\begin{aligned}f^2&=p^2-q^2\\\\5^2&=(\sqrt{41})^2-q^2\\\\41-25&=q^2\\\\4&=q\end{aligned}$
    
   Therefore, the minor radius is $4$ units.

   Matching the major and minor radii with the vertical and horizontal radii
   

   Since the foci are located on the $x$-axis, the major radius is the horizontal radius.

   In consequence, the minor radius is the vertical radius.
   

   This means that the vertical radius is $4$ units and the horizontal radius is $\sqrt{41}$ units.

   Writing the equation

   Our ellipse is centered at $(0, 0)$, has a horizontal radius of ‍${\sqrt{41}}$ units and a vertical radius of ‍$4$ units. So it can be represented by the equation below.

   $\begin{aligned}\dfrac{(x - 0)^2}{( {\sqrt{41}})^2} + \dfrac{(y - 0)^2}{{4}^2} &= 1\\\\\\\dfrac{x^2}{{41}} + \dfrac{y^2}{{16}} &= 1 &(\text{Simplify terms})\end{aligned}$
   

   Summary
   

   The ellipse in question can be represented by the following equation.

   $\dfrac{x^2}{41} + \dfrac{y^2}{ 16} = 1$

   ---

2. The strategy
   

   In order to find the equation of the ellipse, we perform the following steps.
   

   1. Find the focal length, $f$, and the major radius,‍ $q$, using the given information about the center, the foci, and the vertices.

   2. Find the minor radius, $p$, using the equation $f^2=p^2-q^2$.

   3. Match the major and minor radii to the vertical and horizontal radii by determining the axis along which the foci lie.

   4. Substitute all the values we found in the standard equation of an ellipse.

   Finding the focal length and major radius
   

   The focal length is $\sqrt{13}$ units, since the foci are at ‍$(\pm \sqrt{13},0)$.

   The major radius is $11$ units, since the vertices are at ‍$(0,\pm 11)$.

   Finding the minor radius

   We've found that the focal length, $f$, is ‍$\sqrt{13}$ units, and the major radius, ‍$q$, is ‍$11$ units. Let's substitute these values into the equation to find the minor radius, $p$.

   $\begin{aligned}f^2&=p^2-q^2\\\\(\sqrt{13})^2&=p^2-11^2\\\\121+13&=p^2\\\\\sqrt{134}&=p\end{aligned}$
    
   Therefore, the minor radius is $\sqrt{134}$ units.

   Matching the major and minor radii with the vertical and horizontal radii
   

   Since the foci are located on the $x$-axis, the major radius is the horizontal radius.

   In consequence, the minor radius is the vertical radius.
   

   This means that the vertical radius is $11$ units and the horizontal radius is $\sqrt{134}$ units.

   Writing the equation

   Our ellipse is centered at $(0, 0)$, has a horizontal radius of ‍$\sqrt{134}$ units and a vertical radius of ‍$11$ units. So it can be represented by the equation below.

   $\begin{aligned}\dfrac{(x - 0)^2}{( {\sqrt{134}})^2} + \dfrac{(y - 0)^2}{{11}^2} &= 1\\\\\\\dfrac{x^2}{{134}} + \dfrac{y^2}{{121}} &= 1 &(\text{Simplify terms})\end{aligned}$
   

   Summary
   

   The ellipse in question can be represented by the following equation.

   $\dfrac{x^2}{134} + \dfrac{y^2}{ 121} = 1$

   ---

3. The strategy
   

   In order to find the equation of the ellipse, we perform the following steps.
   

   1. Find the focal length, $f$, and the major radius,‍ $p$, using the given information about the center, the foci, and the vertices.

   2. Find the minor radius, $q$, using the equation $f^2=p^2-q^2$.

   3. Match the major and minor radii to the vertical and horizontal radii by determining the axis along which the foci lie.

   4. Substitute all the values we found in the standard equation of an ellipse.

   Finding the focal length and major radius
   

   The focal length is $8$ units, since the foci are at ‍$(\pm 8,0)$.

   The major radius is $17$ units, since the vertices are at ‍$(\pm 17,0)$.

   Finding the minor radius

   We've found that the focal length, $f$, is ‍$8$ units, and the major radius, ‍$p$, is ‍$17$ units. Let's substitute these values into the equation to find the minor radius, $q$.

   $\begin{aligned}f^2&=p^2-q^2\\\\8^2&=17^2-q^2\\\\289-64&=q^2\\\\15&=q\end{aligned}$
    
   Therefore, the minor radius is $15$ units.

   Matching the major and minor radii with the vertical and horizontal radii
   

   Since the foci are located on the $x$-axis, the major radius is the horizontal radius.

   In consequence, the minor radius is the vertical radius.
   

   This means that the vertical radius is $15$ units and the horizontal radius is $17$ units.

   Writing the equation

   Our ellipse is centered at $(0, 0)$, has a horizontal radius of ‍$17$ units and a vertical radius of ‍$15$ units. So it can be represented by the equation below.

   $\begin{aligned}\dfrac{(x - 0)^2}{{17}^2} + \dfrac{(y - 0)^2}{{15}^2} &= 1\\\\\\\dfrac{x^2}{{289}} + \dfrac{y^2}{{225}} &= 1 &(\text{Simplify terms})\end{aligned}$
   

   Summary
   

   The ellipse in question can be represented by the following equation.

   $\dfrac{x^2}{289} + \dfrac{y^2}{ 225} = 1$

   ---

4. The strategy
   

   In order to find the equation of the ellipse, we perform the following steps.
   

   1. Find the focal length, $f$, and the major radius,‍ $p$, using the given information about the center, the foci, and the vertices.

   2. Find the minor radius, $q$, using the equation $f^2=p^2-q^2$.

   3. Match the major and minor radii to the vertical and horizontal radii by determining the axis along which the foci lie.

   4. Substitute all the values we found in the standard equation of an ellipse.

   Finding the focal length and major radius
   

   The focal length is $\sqrt{8}$ units, since the foci are at ‍$(\pm \sqrt{8},0)$.

   The major radius is $\sqrt{10}$ units, since the vertices are at ‍$(0,\pm \sqrt{10})$.

   Finding the minor radius

   We've found that the focal length, $f$, is ‍$\sqrt{8}$ units, and the major radius, ‍$p$, is ‍$\sqrt{10}$ units. Let's substitute these values into the equation to find the minor radius, $q$.

   $\begin{aligned}f^2&=p^2-q^2\\\\(\sqrt{8})^2&=p^2-(\sqrt{10})^2\\\\8+10&=p^2\\\\\sqrt{18}&=p\end{aligned}$
    
   Therefore, the minor radius is $\sqrt{18}$ units.

   Matching the major and minor radii with the vertical and horizontal radii
   

   Since the foci are located on the $x$-axis, the major radius is the horizontal radius.

   In consequence, the minor radius is the vertical radius.
   

   This means that the vertical radius is $\sqrt{10}$ units and the horizontal radius is $\sqrt{18}$ units.

   Writing the equation

   Our ellipse is centered at $(0, 0)$, has a horizontal radius of ‍$\sqrt{18}$ units and a vertical radius of ‍$\sqrt{10}$ units. So it can be represented by the equation below.

   $\begin{aligned}\dfrac{(x - 0)^2}{( {\sqrt{18}})^2} + \dfrac{(y - 0)^2}{({\sqrt{10}})^2} &= 1\\\\\\\dfrac{x^2}{{18}} + \dfrac{y^2}{{10}} &= 1 &(\text{Simplify terms})\end{aligned}$
   

   Summary
   

   The ellipse in question can be represented by the following equation.

   $\dfrac{x^2}{18} + \dfrac{y^2}{ 10} = 1$