Find the coordinates of the foci, the vertices, the length of the major axis, the minor axis, the eccentricity, and the length of the latus rectum of the ellipse \(16x^2+y^2=17\)
Find the coordinates of the foci, the vertices, the length of the major axis, the minor axis, the eccentricity, and the length of the latus rectum of the ellipse \(16x^2+y^2=17\)
Solution and Explanation
The given equation is \(16x^2+y^2=16\)
It can be written as
\(16x^2+y^2=16\)
or \(\dfrac{x^2}{1} + \dfrac{y^2}{16} = 1 \)
or \(\dfrac{x^2}{1^2} + \dfrac{y^2}{4^2} = 1 \)
Here, the denominator of \(\dfrac{y^2}{4^2}\) is greater than the denominator of \(\dfrac{x^2}{1^2}.\)
Therefore, the major axis is along the y-axis, while the minor axis is along the x-axis.
On comparing the given equation (1) with \(\dfrac{x^2}{b^2} + \dfrac{y^2}{a^2} = 1\), we obtain \(b = 1\) and \(a =4\).
\(∴c = √(a^2 – b^2)\)
\(= √(16-1)\)
\(= √15\)
Therefore,
The coordinates of the foci are \((0, ±√15).\)
The coordinates of the vertices are \((0, ±4). \)
Length of major axis = \(2a= 8\)
Length of the minor axis = \(2b = 2\)
Eccentricity,\(e = \dfrac{c}{a} = \dfrac{√15}{4}\)
Length of latus rectum = \(\dfrac{2b^2}{a} = \dfrac{(2×12)}{4} = \dfrac{2}{4} = \dfrac{1}{2}\)
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Concepts Used:
Ellipse
Ellipse Shape
An ellipse is a locus of a point that moves in such a way that its distance from a fixed point (focus) to its perpendicular distance from a fixed straight line (directrix) is constant. i.e. eccentricity(e) which is less than unity
Properties
- Ellipse has two focal points, also called foci.
- The fixed distance is called a directrix.
- The eccentricity of the ellipse lies between 0 to 1. 0≤e<1
- The total sum of each distance from the locus of an ellipse to the two focal points is constant
- Ellipse has one major axis and one minor axis and a center
Read More: Conic Section
Eccentricity of the Ellipse
The ratio of distances from the center of the ellipse from either focus to the semi-major axis of the ellipse is defined as the eccentricity of the ellipse.
The eccentricity of ellipse, e = c/a
Where c is the focal length and a is length of the semi-major axis.
Since c ≤ a the eccentricity is always greater than 1 in the case of an ellipse.
Also,
c2 = a2 – b2
Therefore, eccentricity becomes:
e = √(a2 – b2)/a
e = √[(a2 – b2)/a2] e = √[1-(b2/a2)]
Area of an ellipse
The area of an ellipse = πab, where a is the semi major axis and b is the semi minor axis.
Position of point related to Ellipse
Let the point p(x1, y1) and ellipse
(x2 / a2) + (y2 / b2) = 1
If [(x12 / a2)+ (y12 / b2) − 1)]
= 0 {on the curve}
<0{inside the curve}
>0 {outside the curve}