We have now seen a few conic sections including circles and parabolas. Now we will look at ellipses. Circles are just a special case of an ellipse.
The classic example of constructing an ellipse is to place two pins some distance apart. Tie each end of a string around each pin and then pull the string taut with a pencil. Then trace the curve that the string will allow, keeping it taut.
Try this in the applet below. The two pins are located at $F$F and $F'$F′. The pencil is located at the point $P$P.
|
The shape created in this way is always an ellipse. The points located at the pins are the foci (or focus if singular).
Notice that the length of the string never changes. So the length of string from one focus to a point on the ellipse added to the length of string from the other focus to the same point will always equal a constant for that ellipse. The constant for the above ellipse is $4$4.
The distance from one foci to a point on the ellipse added to the distance from the other foci to the same point is equal to a constant for the same ellipse.
$FP+F’P=\text{constant}$FP+F’P=constant
Consider the ellipse below.
Find the value of $x$x.
Think: A pair of lines meeting at a point on the ellipse from the foci will have the same total length. There are two pairs of these lines on this ellipse. The sum of one pair must be equal to the sum of the other pair.
Do: Construct an equation relating the length of the two pairs of lines and solve for $x$x.
$GP+FP$GP+FP | $=$= | $GQ+FQ$GQ+FQ | |
$x+x$x+x | $=$= | $9+3$9+3 | (Substitution) |
$2x$2x | $=$= | $12$12 | (Collecting like terms) |
$x$x | $=$= | $6$6 | (Dividing both sides by $2$2) |
The following applet allows you to investigate the string and pin construction of an ellipse. You can vary the distance between the pins (foci) and change the length of the string. You can trace out the path yourself by dragging the point around (make sure the Trace button is ON), or let the animation button trace it for you.
|
Consider the following ellipse. The points given are the foci of the ellipse. Find the value of $x$x.
Mario picks out a piece of string $8$8 inches long. He fixes each end of the string at points $F$F and $G$G on a chalkboard as shown, such that $F$F and $G$G are $6$6 inches apart and equidistant to point $O$O. He pulls the string taut and then uses chalk to trace out the curve shown below.
What is the length of $\overline{OF}$OF?
What is the length of $\overline{FR}$FR?
What is the length of $\overline{OR}$OR?
What is the length of $\overline{FP}$FP?
What is the length of $\overline{OP}$OP?
An ellipse centered at the origin has one of two equations depending on whether the longer diameter is horizontal or vertical.
If an ellipse has its major axis (longest diameter) along the $x$x-axis and its minor axis (shortest diameter) along the $y$y-axis, the equation of the ellipse is $\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$x2a2+y2b2=1 where:
Half of the major axis is referred to as the semi-major axis, and half of the minor axis is referred to as the semi-minor axis. So we can say that $a$a is the length of the semi-major axis, and $b$b is the length of the semi-minor axis.
Graph of ellipse with equation $\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$x2a2+y2b2=1 where $a>b$a>b. |
If we swap the position of $a$a and $b$b, we get the equation $\frac{x^2}{b^2}+\frac{y^2}{a^2}=1$x2b2+y2a2=1 where $a>b$a>b with the following graph. We call these two equations the standard form of the ellipse centered at the origin.
Graph of ellipse with equation $\frac{x^2}{b^2}+\frac{y^2}{a^2}=1$x2b2+y2a2=1 where $a>b$a>b. |
We call the endpoints of the major axis the vertices, and the endpoints of the minor axis the co-vertices. In the special case that the ellipse is centered at the origin, then these points represent the $x$x- and $y$y-intercepts.
Vertices and co-vertices of an ellipse. |
If the vertices lie on the $x$x-axis, then their coordinates are $\left(-a,0\right)$(−a,0) and $\left(a,0\right)$(a,0). If they lie on the $y$y-axis then their coordinates are $\left(0,-a\right)$(0,−a) and $\left(0,a\right)$(0,a).
Similarly, if the co-vertices lie on the $x$x-axis, then they have coordinates $\left(-b,0\right)$(−b,0) and $\left(b,0\right)$(b,0). If they lie on the $y$y-axis then their coordinates are $\left(0,-b\right)$(0,−b) and $\left(0,b\right)$(0,b).
We might also be curious about identifying the foci of a given ellipse. From our definition of the ellipse, the foci represent two points on the major axis such that their sum of the distances to the ellipse is always constant.
Construction of the ellipse from two foci. |
Recall from the definition of the ellipse, we start with the foci $\left(-c,0\right)$(−c,0) and $\left(c,0\right)$(c,0) and arrive at the equation of the ellipse where $c^2=a^2-b^2$c2=a2−b2.
Similarly, if we started with the foci $\left(0,-c\right)$(0,−c) and $\left(0,c\right)$(0,c), then we can obtain the same equation $c^2=a^2-b^2$c2=a2−b2.
Alternatively, knowing the values of $a$a and $b$b, we can find the coordinates of the two foci using the equation $c^2=a^2-b^2$c2=a2−b2.
Consider the ellipse with the equation $\frac{x^2}{9^2}+\frac{y^2}{4^2}=1$x292+y242=1.
a) What are the coordinates of the two vertices?
Think: The vertices are the endpoints of the major axis. The major axis lies on the $x$x-axis, so the vertices will be of the form $\left(-a,0\right)$(−a,0) and $\left(a,0\right)$(a,0).
Do: Since $a=9$a=9, the vertices are $\left(-9,0\right)$(−9,0) and $\left(9,0\right)$(9,0).
b) What are the coordinates of the two co-vertices?
Think: The co-vertices are the endpoints of the minor axis. The minor axis lies on the $y$y-axis, so the vertices will be of the form $\left(0,-b\right)$(0,−b) and $\left(0,b\right)$(0,b).
Do: Since $b=4$b=4, the co-vertices are $\left(0,-4\right)$(0,−4) and $\left(0,4\right)$(0,4).
c) What are the coordinates of the foci?
Think: The distance $c$c from the center to a focus of the ellipse is related to the semi-major and semi-minor axes by the equation $c^2=a^2-b^2$c2=a2−b2. We can substitute the known values for $a$a and $b$b, and then solve for $c$c.
Do:
$c^2$c2 | $=$= | $a^2-b^2$a2−b2 | (Writing the equation) |
$c^2$c2 | $=$= | $9^2-4^2$92−42 | (Substitution) |
$c^2$c2 | $=$= | $81-16$81−16 | (Simplifying the squares) |
$c^2$c2 | $=$= | $65$65 | (Simplifying the subtraction) |
$c$c | $=$= | $\sqrt{65}$√65 | (Taking the square root) |
The ellipse is centered at the origin, so the coordinates of the foci are $\left(-\sqrt{65},0\right)$(−√65,0) and $\left(\sqrt{65},0\right)$(√65,0).
Reflect: How might the coordinates of the foci change if the equation of the ellipse was $\frac{x^2}{4^2}+\frac{y^2}{9^2}=1$x242+y292=1?
Consider the graph of the ellipse drawn below.
What are the coordinates of the center of the ellipse?
What is the length of the major axis?
What is the length of the minor axis?
What are the coordinates of the two vertices? Write each pair of coordinates on the same line, separated by a comma.
What are the coordinates of the two co-vertices? Write each pair of coordinates on the same line, separated by a comma.
Consider the ellipse with equation $\frac{x^2}{6^2}+\frac{y^2}{10^2}=1$x262+y2102=1.
What is the length $a$a of the semi-major axis?
What is the length $b$b of the semi-minor axis?
Find the distance $c$c between the center and a focus of the ellipse.
State the coordinates of the foci of the ellipse. Write each pair of coordinates on the same line, separated by a comma.
Consider the ellipse given by the equation $100x^2+36y^2=3600$100x2+36y2=3600.
Rewrite the equation in the form $\frac{x^2}{b^2}+\frac{y^2}{a^2}=1$x2b2+y2a2=1 where $a>b$a>b.
Is the major axis of the ellipse horizontal or vertical?
Horizontal
Vertical
Determine the length of the major axis.
What is the length of the minor axis?
Find the distance $c$c between the center and a focus of the ellipse.
State the coordinates of the foci of the ellipse. Write each pair of coordinates on the same line, separated by a comma.
Now sketch the graph of this ellipse, and plot its focal points.
To summarize characteristics above, we can start by finding a standard form for ellipses with center at $\left(0,0\right)$(0,0).
The standard form for a central ellipse depends on the orientation of the ellipse. The equations and attributes can be summarized in the table below, given the following:
Orientation | Horizontal Major Axis | Vertical Major Axis |
---|---|---|
Standard form | $\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$x2a2+y2b2=1 | $\frac{x^2}{b^2}+\frac{y^2}{a^2}=1$x2b2+y2a2=1 |
Center | $\left(0,0\right)$(0,0) | $\left(0,0\right)$(0,0) |
Foci | $\left(c,0\right)$(c,0) and $\left(-c,0\right)$(−c,0) | $\left(0,c\right)$(0,c) and $\left(0,-c\right)$(0,−c) |
Vertices | $\left(a,0\right)$(a,0) and $\left(-a,0\right)$(−a,0) | $\left(0,a\right)$(0,a) and $\left(0,-a\right)$(0,−a) |
Covertices | $\left(0,b\right)$(0,b) and $\left(0,-b\right)$(0,−b) | $\left(b,0\right)$(b,0) and $\left(-b,0\right)$(−b,0) |
Major axis | $y=0$y=0 | $x=0$x=0 |
Minor axis | $x=0$x=0 | $y=0$y=0 |
Notice that by this definition, it is always true that $a>b$a>b. It is also true that the parameters $a$a, $b$b, and $c$c have the relationship $c^2=a^2-b^2$c2=a2−b2.
If an ellipse is translated horizontally or vertically from the center, the parameter $a$a, $b$b, and $c$c still have the same meaning. However, we must take into account that the center of the ellipse has moved. Given the following definitions for $h$h and $k$k,
The table below summarizes the standard form of an ellipse in both orientations.
Orientation | Horizontal Major Axis | Vertical Major Axis |
---|---|---|
Standard form | $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 | $\frac{\left(x-h\right)^2}{b^2}+\frac{\left(y-k\right)^2}{a^2}=1$(x−h)2b2+(y−k)2a2=1 |
Center | $\left(h,k\right)$(h,k) | $\left(h,k\right)$(h,k) |
Foci | $\left(h+c,k\right)$(h+c,k) and $\left(h-c,k\right)$(h−c,k) | $\left(h,k+c\right)$(h,k+c) and $\left(h,k-c\right)$(h,k−c) |
Vertices | $\left(h+a,k\right)$(h+a,k) and $\left(h-a,k\right)$(h−a,k) | $\left(h,k+a\right)$(h,k+a) and $\left(h,k-a\right)$(h,k−a) |
Covertices | $\left(h,k+b\right)$(h,k+b) and $\left(h,k-b\right)$(h,k−b) | $\left(h+b,k\right)$(h+b,k) and $\left(h-b,k\right)$(h−b,k) |
Major axis | $y=k$y=k | $x=h$x=h |
Minor axis | $x=h$x=h | $y=k$y=k |
Essentially, the information is the same as the central ellipse. But the values of $h$h and $k$k are added to the $x$x and $y$y values (respectively) for each characteristic.
Find the equation, in standard form, of the ellipse with $x$x-intercepts $\left(\pm3,0\right)$(±3,0) and $y$y-intercepts $\left(0,\pm7\right)$(0,±7).
Find the equation, in standard form, of the ellipse with foci $\left(\pm6,0\right)$(±6,0) and a minor axis of length $6$6.
Find the equation, in standard form, of the ellipse with center $\left(1,5\right)$(1,5), a horizontal major axis of length $16$16 and a minor axis of length $10$10.
It takes some skill to sketch an ellipse free hand, but with practice it does get easier.
While most modern graphing software or calculators can handle implicit forms (such as the standard form of an ellipse), it is probably a good idea to predict, with a rough sketch, what the technology should deliver.
It can be very helpful to graph by identifying the key points such as the center, vertices, and co-vertices. We can then plot those points and sketch the ellipse. Sometimes, it may help us to draw a rectangular frame to help with the shape.
In standard form, the ellipse centered at $\left(0,0\right)$(0,0) has the equation $\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$x2a2+y2b2=1. The standard form informs us that the domain is given by $\left\{x:-a\le x\le a\right\}${x:−a≤x≤a} and the range is given by $\left\{y:-b\le y\le b\right\}${y:−b≤y≤b}. We can lightly pencil in a rectangle of these dimensions to use as our guide, as shown here:
Draw in the four parts of the curve where it becomes tangent to the rectangle, then complete the sketch trying to make it as symmetric as possible as you do so.
If the ellipse happens to be of non-central form, with the equation given by $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 then apply the same strategy but this time with the the center of the rectangle positioned at $\left(h,k\right)$(h,k). Note that the length of the rectangle is $2a$2a and the height is $2b$2b.
Sketch the graph of $\frac{\left(x-3\right)^2}{16}+\frac{\left(y-1\right)^2}{25}=1$(x−3)216+(y−1)225=1.
Think: We can start by drawing a rectangle as demonstrated above, but first we need to know the coordinates of the vertices and co-vertices. It is important to note from the beginning that since the larger denominator is under the $\left(y-k\right)^2$(y−k)2 term, the major axis will be vertical.
Do:
For this ellipse, we have the following:
From our table above, we know that the vertices are $\left(h,k+a\right)$(h,k+a) and $\left(h,k-a\right)$(h,k−a). and that our covertices are $\left(h+b,k\right)$(h+b,k) and $\left(h-b,k\right)$(h−b,k).
Center | $\left(3,1\right)$(3,1) |
Vertices | $\left(3,6\right)$(3,6) and $\left(3,-4\right)$(3,−4) |
Covertices | $\left(7,1\right)$(7,1) and $\left(-1,1\right)$(−1,1) |
Major axis | $x=3$x=3 |
Minor axis | $y=1$y=1 |
Now that we have these features, we can graph!
Sketch the graph of the equation $\frac{x^2}{25}+\frac{y^2}{16}=1$x225+y216=1
Consider the ellipse with equation $x^2+25y^2=25$x2+25y2=25.
Write the equation in standard form $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 where $a>b$a>b.
Draw the graph of the ellipse.
Consider the ellipse with equation $4x^2+25y^2-16x+150y+141=0$4x2+25y2−16x+150y+141=0.
Rewrite the equation in standard form $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 where $a>b$a>b.
Draw the graph of the ellipse.
The domain is the set of $x$x-values of the relation and the range is the set of $y$y-values of the relation. One example of a relation is an ellipse. An ellipse that is centered at the point $\left(h,k\right)$(h,k) which has a semi-major axis of length $a$a units and semi-minor axis of length $b$b units can be described by the following equation and graph.
The graph of $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 for $a>b$a>b. |
The graph of the ellipse is horizontally bound by two vertical lines, one at $x=h-a$x=h−a and the other at $x=h+a$x=h+a. Because of this, the domain of the ellipse is $\left[h-a,h+a\right]$[h−a,h+a].
The ellipse bound by two vertical lines. |
Similarly, the ellipse is bound by two vertical lines, one at $y=k-b$y=k−b and the other at $y=k+b$y=k+b and so the range of the ellipse is $\left[k-b,k+b\right]$[k−b,k+b].
The ellipse bound by two horizontal lines. |
If we swap the length of the semi-major axis $a$a with the length of the semi-minor axis $b$b, we get the following equation and graph.
The graph of $\frac{\left(x-h\right)^2}{b^2}+\frac{\left(y-k\right)^2}{a^2}=1$(x−h)2b2+(y−k)2a2=1 for $a>b$a>b. |
And because we've swapped $a$a and $b$b, the domain of the ellipse becomes $\left[h-b,h+b\right]$[h−b,h+b] and the range becomes $\left[k-a,k+a\right]$[k−a,k+a].
For an ellipse of the form $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 where $a>b$a>b:
The domain is equal to $\left[h-a,h+a\right]$[h−a,h+a] and the range is equal to $\left[k-b,k+b\right]$[k−b,k+b].
For an ellipse of the form $\frac{\left(x-h\right)^2}{b^2}+\frac{\left(y-k\right)^2}{a^2}=1$(x−h)2b2+(y−k)2a2=1 where $a>b$a>b:
The domain is equal to $\left[h-b,h+b\right]$[h−b,h+b] and the range is equal to $\left[k-a,k+a\right]$[k−a,k+a].
In the special case that the ellipse is centered at the origin, that is $\left(h,k\right)=\left(0,0\right)$(h,k)=(0,0), then the domain and range of the ellipse only depend on the values of $a$a and $b$b.
Find the domain and range of the ellipse $\frac{\left(x+3\right)^2}{25}+\frac{\left(x-5\right)^2}{16}=1$(x+3)225+(x−5)216=1.
Think: The equation of the ellipse is of the form $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 where $a>b$a>b. The domain of such an ellipse is given by $\left[h-a,h+a\right]$[h−a,h+a] and the range is $\left[k-b,k+b\right]$[k−b,k+b].
Do: In our case we have $h=-3$h=−3 and $a=5$a=5 so the domain of the ellipse is $\left[-3-5,-3+5\right]$[−3−5,−3+5] which simplifies to $\left[-8,2\right]$[−8,2].
We also know that $k=5$k=5 and $b=4$b=4 so the range of the ellipse is $\left[5-4,5+4\right]$[5−4,5+4] which simplifies to $\left[1,9\right]$[1,9].
Reflect: How might the domain and range differ if we swapped the semi-major and semi-minor axes?
Draw the graph of the ellipse with equation $\frac{\left(x-3\right)^2}{16}+\frac{\left(y+3\right)^2}{25}=1$(x−3)216+(y+3)225=1.
Consider the graph of the ellipse drawn below.
What is the domain of the ellipse?
Write the answer as an interval.
What is the range of the ellipse?
Write the answer as an interval.
Typically we are given the equation of an ellipse in the standard form $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 or $\frac{\left(x-h\right)^2}{b^2}+\frac{\left(y-k\right)^2}{a^2}=1$(x−h)2b2+(y−k)2a2=1 where $a>b$a>b. Ideally we would like to express any equation of an ellipse in such a way, since we can immediately identify its center and the length of the semi-major and semi-minor axes:
But generally speaking, the equation of an ellipse can be expressed in many ways. For instance, the following pair of equations both represent the same ellipse.
$9\left(x-2\right)^2+4\left(y-3\right)^2=36$9(x−2)2+4(y−3)2=36 or $9x^2-36x+4y^2-24x=-36$9x2−36x+4y2−24x=−36
In order to express the above equations in standard form, we can manipulate both sides by multiplying or by completing the square.
Consider the equation of the ellipse $x^2-12x+36y^2=0$x2−12x+36y2=0
Rewrite the equation in the standard form $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 where $a>b$a>b.
Think: Completing the square allows us to rewrite the quadratic expressions in $x$x as a perfect square of the form $\left(x-h\right)^2$(x−h)2. Notice that the quadratic expression in $y$y is already a perfect square.
To complete the square in $x$x we look at the expression $x^2-12x$x2−12x, halve and square the coefficient of $x$x, and then add the result to both sides of the equation.
Do: Halving and squaring $-12$−12 gives a result of $36$36, so we add this result to both sides of the equation:
$x^2-12x+36+36y^2=36$x2−12x+36+36y2=36
So altogether we get the following steps:
$x^2-12x+36y^2$x2−12x+36y2 | $=$= | $0$0 | (Writing down the equation) |
$x^2-12x+36+36y^2$x2−12x+36+36y2 | $=$= | $36$36 | (Completing the square for $x$x) |
$\left(x-6\right)^2+36y^2$(x−6)2+36y2 | $=$= | $36$36 | (Factoring the perfect square) |
$\frac{\left(x-6\right)^2}{36}+y^2$(x−6)236+y2 | $=$= | $1$1 | (Dividing both sides by $36$36) |
The equation of the ellipse is then $\frac{\left(x-6\right)^2}{36}+y^2=36$(x−6)236+y2=36. Optionally, the standard form can be made more obvious by writing it as $\frac{\left(x-6\right)^2}{6^2}+\frac{y^2}{1^2}=36$(x−6)262+y212=36.
Reflect: The equation of the ellipse centered at $\left(6,0\right)$(6,0) with a vertical semi-major axis of length $6$6 units and a horizontal semi-minor axis of length $1$1 unit can be expressed by the equation $x^2-12x+36y^2=0$x2−12x+36y2=0 or the equation $\frac{\left(x-6\right)^2}{36}+y^2=1$(x−6)236+y2=1.
Consider the equation of the ellipse $9x^2-36x+4y^2-24x=-36$9x2−36x+4y2−24x=−36.
Rewrite the equation in the standard form $\frac{\left(x-h\right)^2}{b^2}+\frac{\left(y-k\right)^2}{a^2}=1$(x−h)2b2+(y−k)2a2=1 where $a>b$a>b.
Think: Completing the square allows us to rewrite the terms containing $x$x and $y$y in the form $\left(x-h\right)^2$(x−h)2 and $\left(y-k\right)^2$(y−k)2. Before we do so, it will be more convenient if we factor so that the coefficients of $x^2$x2 and $y^2$y2 are $1$1.
Do: In this case, the coefficient of $x^2$x2 is $9$9 the coefficient of $y^2$y2 is $4$4:
$9\left(x^2-4x\right)+4\left(y^2-6x\right)=-36$9(x2−4x)+4(y2−6x)=−36
Now we can complete the square in $x$x and $y$y:
$9\left(x^2-4x+4\right)+4\left(y^2-6x+9\right)=-36+9\times4+4\times9$9(x2−4x+4)+4(y2−6x+9)=−36+9×4+4×9
Putting this together, we get the following steps:
$9x^2-36x+4y^2-24x$9x2−36x+4y2−24x | $=$= | $-36$−36 | (Writing down the equation) |
$9\left(x^2-4x\right)+4\left(y^2-6x\right)$9(x2−4x)+4(y2−6x) | $=$= | $-36$−36 | (Factoring the leading coefficients of each variable) |
$9\left(x^2-4x+4\right)+4\left(y^2-6x+9\right)$9(x2−4x+4)+4(y2−6x+9) | $=$= | $-36+9\times4+4\times9$−36+9×4+4×9 | (Completing the square for $x$x and $y$y) |
$9\left(x^2-4x+4\right)+4\left(y^2-6x+9\right)$9(x2−4x+4)+4(y2−6x+9) | $=$= | $36$36 | (Simplifying the constant terms) |
$9\left(x-2\right)^2+4\left(y-3\right)^2$9(x−2)2+4(y−3)2 | $=$= | $36$36 | (Rewriting the perfect squares in factored form) |
$\frac{\left(x-2\right)^2}{4}+\frac{\left(y-3\right)^2}{9}$(x−2)24+(y−3)29 | $=$= | $1$1 | (Dividing both sides by $36$36) |
So the equation of the ellipse can be expressed in the form $\frac{\left(x-2\right)^2}{4}+\frac{\left(y-3\right)^2}{9}=1$(x−2)24+(y−3)29=1.
Reflect: The center of the ellipse is $\left(h,k\right)=\left(2,3\right)$(h,k)=(2,3), the length of the vertical semi-major axis is $3$3 units and the length of the horizontal semi-minor axis is $2$2 units. From this, we can draw the equation of the ellipse as shown below.
Graph of the ellipse $9x^2-36x+4y^2-24x=-36$9x2−36x+4y2−24x=−36. |
Consider the ellipse with equation $\left(x+3\right)^2+4\left(y-1\right)^2=16$(x+3)2+4(y−1)2=16.
Write the equation in standard form $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 where $a>b$a>b.
Draw the graph of the ellipse.
The graph of the ellipse $\frac{x^2}{9}+\frac{y^2}{4}=1$x29+y24=1 is given below.
Write $4x^2+9\left(y-2\right)^2=36$4x2+9(y−2)2=36 in the standard form $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 where $a>b$a>b.
What transformation of the ellipse drawn gives the ellipse $4x^2+9\left(y-2\right)^2=36$4x2+9(y−2)2=36?
Translated to the right by $2$2 units
Translated to the left by $2$2 units
Translated up by $2$2 units
Translated down by $2$2 units
Consider the ellipse with equation $4x^2+24x+5y^2+20y+36=0$4x2+24x+5y2+20y+36=0.
Rewrite the equation in the standard form $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 where $a>b$a>b.
What are the coordinates of the center of the ellipse?
What are the coordinates of the vertices?
Below are two images with the important features of an ellipse:
Horizontally aligned ellipse | Vertically aligned ellipse |
The standard form for a central ellipse depends on the orientation of the ellipse. The equations and attributes are summarized in the table below, given the following:
Notice that by this definition, it is always true that $a>b$a>b. It is also true that the parameters $a$a, $b$b, and $c$c have the relationship $c^2=a^2-b^2$c2=a2−b2.
If an ellipse is translated horizontally or vertically from the origin, the parameter $a$a, $b$b, and $c$c still have the same meaning. However, we must take into account that the center of the ellipse has moved. Given the following definitions for $h$h and $k$k,
An ellipse translated horizontally by $h$h and vertically by $k$k. |
The table below summarizes the standard form of an ellipse in both orientations.
Orientation | Horizontal Major Axis | Vertical Major Axis |
---|---|---|
Standard form | $\frac{\left(x-h\right)^2}{a^2}+\frac{\left(y-k\right)^2}{b^2}=1$(x−h)2a2+(y−k)2b2=1 | $\frac{\left(x-h\right)^2}{b^2}+\frac{\left(y-k\right)^2}{a^2}=1$(x−h)2b2+(y−k)2a2=1 |
Center | $\left(h,k\right)$(h,k) | $\left(h,k\right)$(h,k) |
Foci | $\left(h+c,k\right)$(h+c,k) and $\left(h-c,k\right)$(h−c,k) | $\left(h,k+c\right)$(h,k+c) and $\left(h,k-c\right)$(h,k−c) |
Vertices | $\left(h+a,k\right)$(h+a,k) and $\left(h-a,k\right)$(h−a,k) | $\left(h,k+a\right)$(h,k+a) and $\left(h,k-a\right)$(h,k−a) |
Co-vertices | $\left(h,k+b\right)$(h,k+b) and $\left(h,k-b\right)$(h,k−b) | $\left(h+b,k\right)$(h+b,k) and $\left(h-b,k\right)$(h−b,k) |
Major axis | $y=k$y=k | $x=h$x=h |
Minor axis | $x=h$x=h | $y=k$y=k |
Essentially, the information is the same as the central ellipse. But the values of $h$h and $k$k are added to the $x$x and $y$y-values (respectively) for each characteristic.
Orbits around a planetary body are described by the conic sections (circle, ellipse, parabola and hyperbola).
Elliptical orbits around the Sun. Not to scale. |
The orbits of the planets around the Sun and the moon around the Earth are all elliptical (some are very close to circular though). The larger mass being orbited will be at one of the foci of the ellipse. For example, the Sun will be at one of the foci of the Earth's ellipse.
At the closest point in its orbit (Perihelion) Mercury is $0.31$0.31 AU away from the Sun. At its furthest point in its orbit (Aphelion) it is $0.36$0.36 AU from the Sun. Find the equation of Mercury's orbit around the Sun. Give your values to two decimal places in AU.
Think: The equation of the ellipse will be in the form $\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$x2a2+y2b2=1. We can find the values of $a$a and $c$c using the geometry of the ellipse. The value of $b$b can be found given that $c^2=a^2-b^2$c2=a2−b2.
From the image above we can see that the value of $a$a will be $\frac{0.31+0.36}{2}$0.31+0.362 and $c$c will be $\frac{0.36-0.31}{2}$0.36−0.312.
Do: Solve for $a$a and $c$c and then sub into equation for $b$b.
$a$a | $=$= | $\frac{0.31+0.36}{2}$0.31+0.362 |
$=$= | $0.335$0.335 | |
$c$c | $=$= | $\frac{0.36-0.31}{2}$0.36−0.312 |
$=$= | $0.025$0.025 | |
$b$b | $=$= | $\sqrt{a^2-c^2}$√a2−c2 |
$=$= | $\sqrt{0.335^2-0.025^2}$√0.3352−0.0252 | |
$\approx$≈ | $0.334$0.334 (3 d.p.) |
If we create our $xy$xy plane so the major axis is aligned with $x$x-axis and the $y$y-axis is aligned with the minor axis we can determine the equation of the orbit.
$\frac{x^2}{0.335^2}+\frac{y^2}{0.334^2}=1$x20.3352+y20.3342=1
Here are a few terms that often appear in questions about orbits:
Note: "Peri-" means closest point to and "apo-" means furthest point from. The next part of the word determines what is being orbited, for example, "-helion" means its orbiting the sun. Similarly "-gee" means its orbiting Earth, and "-jove" orbiting Jupiter.
We want to figure out if a truck that is $8$8 feet wide carrying a load that reaches $6$6 feet above the ground will clear the semielliptical archway shown in the figure?
Find the equation for the bridge in terms of $y$y, the height of the bridge, $x$x meters from the center of the archway.
Use a coordinate system with the $x$x-axis on the ground and the origin $\left(0,0\right)$(0,0) at the center of the archway.
Give your answer in the standard form for the equation of an ellipse (rather than a semiellipse).
Solve for $y$y, the height of the archway $4$4 feet from the center.
Give your answer to the nearest hundredth of a foot.
Will the truck clear the bridge?
Yes
No
The Juno spacecraft entered an elliptical orbit around Jupiter in July 2016. It will perform $33$33 orbits during its mission. In 2021 the mission will be complete and the spacecraft will be deliberately driven into the atmosphere to be destroyed.
The formula describing Juno's orbit is $36x^2+400y^2=14400$36x2+400y2=14400, where values are given in RJ (the radius of Jupiter). What is the formula of the elliptical orbit in the form $\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$x2a2+y2b2=1?
Find the distance between Jupiter and Juno at its perijove. Perijove is the point in Juno's orbit where it is closest to Jupiter. Give your answer to two decimal places in RJ.
Find the distance between Jupiter and Juno at its apojove. Apojove is the point in Juno's orbit where it is furthest from Jupiter. Give your answer to two decimal places in RJ.
Kepler's third law relates the orbital period, $T$T in days, and the semi-major axis, $a$a in RJ, with the equation $a^3=2.74T^2$a3=2.74T2.
What is the orbital period of Juno? Give your answer to the nearest day.
If Juno completes its mission, how many days will it have spent orbiting Jupiter before entering its atmosphere?