|
|
Ellipse
|
Equation of a translated ellipse
|
Ellipse, examples |
|
|
|
|
|
Equation of a translated ellipse |
|
Equation of a translated ellipse
-the ellipse with the center at
(x0,
y0)
and the major axis parallel to the x-axis. |
The equation of an ellipse that is translated from its standard position can be obtained by replacing
x
by x0 |
and
y by
y0 in its standard equation, |
|
|
|
The above equation can be rewritten into
Ax2
+ By2 + Cx + Dy + E = 0. |
Every equation of that form represents
an ellipse if A
not equal
B
and A ·
B > 0 that is, if the square terms have unequal coefficients, but the same
signs. |
|
Ellipse, examples |
Example:
Given is equation of the ellipse
9x2
+ 25y2 = 225, find the lengths of semi-major and
semi-minor axes, coordinates of the foci, the eccentricity and the length of the
semi-latus rectum. |
Solution: From the standard equation |
|
we can find the semi-axes
lengths dividing the given |
|
equation by
225, |
|
|
coordinates of the
foci F1(-c, 0) and
F2(
c, 0),
since
|
|
|
|
Example:
Find the equation of
the ellipse whose focus is F2(6,
0) and which passes through the point
A(5Ö3,
4). |
Solution:
Coordinates of the point
A(5Ö3,
4) must satisfy equation of the ellipse, therefore |
|
|
thus,
the equation of the ellipse |
|
|
|
|
Example:
Write equation of the ellipse passing through points
A(-4,
2) and B(8,
1). |
Solution:
Given points must satisfy equation of the ellipse, so |
|
Therefore,
the equation of the ellipse |
|
or
x2
+ 16y2 = 80. |
|
|
Example:
In the ellipse 4x2
+ 9y2 = 144 inscribed is a rectangle whose vertices lie on the ellipse and
whose sides are parallel with ellipse axes. Longer side, which is parallel to the major axis, relates to the shorter
side as 3 :
2. Find the area of the rectangle. |
Solution: It follows from the given condition that the coordinates
of vertices of the rectangle must satisfy the |
same ratio, i.e.,
x :
y
= 3 :
2 =>
x =
3y/2.
|
To determine points of the ellipse of which coordinates are in this ratio, put these variable
coordinates into equation of the ellipse, |
P(3y/2,
y) =>
4x2
+ 9y2 = 144 |
4(3y/2)2
+ 9y2 = 144 =>
18y2 = 144,
|
y1,2 = ±Ö144/18 =
±2Ö2,
x =
3y/2 =>
x1,2 =
±3Ö2.
|
Therefore, the vertices of the rectangle,
|
|
|
|
A(3Ö2,
2Ö2),
B(-3Ö2,
2Ö2),
C(-3Ö2,
-2Ö2)
and D(3Ö2,
-2Ö2). |
The
area of the rectangle A =
4 · x
· y =
4 · (3Ö2
)
· (2Ö2
)
=
48 square units. |
|
Example:
Given is equation of the ellipse
4x2
+ 9y2
+ 24x -18y
+ 9 =
0,
find its center S(x0,
y0),
the semi-axes and intersections of the ellipse with the coordinate axes. |
Solution: Coordinates of the center and the semi-axes are shown
in the equation of the translated ellipse, |
|
Rewrite the given equation to that
form, |
4(x2
+ 6x)
+ 9(y2 -
2y)
+ 9 = 0 |
4[(x + 3)2 -
9] +
9[(y -1)2
-1]
+ 9 = 0
|
4(x + 3)2
+ 9(y -1)2
= 36
or
|
|
|
|
|
therefore,
S(-3,
1),
a = 3 and
b = 2.
|
Intersections of the ellipse and the
x-axis
we obtain by setting y =
0 into the equation of the ellipse, thus
|
4x2
+ 24x + 9 =
0,
x1,2 = -3
± 3Ö3/2, |
and intersections of the ellipse
with the y-axis by
setting x
= 0, =>
9y2
-18y
+ 9 =
0,
y1,2 = 1. |
|
|
|
|
|