Focal Distance of Ellipse: Introduction
The focal distance of an ellipse denotes, basically, the distance of a point on the circumference of the ellipse from any of its foci. Thus, every point on the ellipse displays two focal distances as measured concerning the ellipse's two foci. The sum of the focal distances of any point on an ellipse is constant by the definition of the ellipse. The sum of the focal distances of any point on an ellipse bears a distinct relation to the length of the major axis of the ellipse.
What is the General Equation of an Ellipse?
An ellipse is a conic section with its centre midway between its two foci lying on the major axis. If the centre of an ellipse lies at the coordinate $(h,k)$ and its major and minor axes of the ellipse are parallel to the coordinate axes in the XY plane having the lengths 2a and 2b, respectively, then the equation of the ellipse is given in the following way.
$ \dfrac{(x-h)^{2}}{a^{2}} + \dfrac{(y-k)^{2}}{b^{2}} =1$
What is the Focus of an Ellipse?
The locus or the path of points for which the ratio of distances from a fixed point and the defined straight line is less than 1 is called an ellipse. The fixed point and the straight line are the focus and the directrix of the ellipse, respectively. An ellipse has two points of reference called the focus of the ellipse. These are called foci of the ellipse.
What are the Axes of an Ellipse?
An ellipse is the locus of all points for which the sum of its distances from the two fixed points (called foci) is a constant.
An ellipse has two axes of symmetry.
The two points most far from the centre of the ellipse are called the vertices.
The two points at least a distance from the ellipse's centre are called the co-vertices.
The major axis is the line segment passing through the centre, joining the vertices.
The minor axis is the line segment passing through the centre, joining the co-vertices.
The line segments joining the centre to each vertex are called the semi-major axes.
The line segments joining the centre to each co-vertex are called the semi-minor axes.
How is the Focal Distance Calculated in an Ellipse?
To calculate the focal distances of any point on an ellipse, we proceed in the following steps.
Let P(x,y) be a point on ellipse $\dfrac{x^{2}}{a^{2}} + \dfrac{y^{2}}{b^{2}} =1$.
The directrices of the ellipse are ZK, and Z'K' and its foci are S and S’.
Focal Distance of Ellipse
Point P is connected to the foci S and S’ with the straight lines PS and PS’.
Let us draw NPN' as the perpendicular through the point P on directrices ZK and Z'K'.
Now by definition of the eccentricity of an ellipse, we get,
SP = e.PN
SP = e.RZ
SP = e (OZ - OR)
SP = e(a/e - x)
SP = a - ex ………… (1)
And
S'P = e ∙ PN'
S'P = e ∙ (RZ')
S'P = e (OZ' + OR)
S'P = e (x + a/e)
S'P = a + ex ………. (2)
Calculating the value of SP + S'P = a - ex + a + ex = 2a = major axis.
Hence, it is proved that the sum of the focal distances of any point on an ellipse is constant and always equal to the length of the ellipse's major axis.
What is the Focal Chord of an Ellipse?
A focal chord is a chord that passes through the focus of an ellipse. A focal chord is an essential tool to solve many problems in geometry. We can determine the major and the minor axes in an ellipse with the help of the length of the focal chord. The ellipse's focal width is the focal chord's length perpendicular to the major axis and passes through one of the foci with the endpoints on the ellipse.
Length of the Focal Chord of the Ellipse
To calculate the length of the focal chord of an ellipse, we proceed with the following steps. The foci of an ellipse are S and S’.
Length of the Focal Chord of the Ellipse
Let us suppose that the focal chord PQ is inclined to the major axis at angles t and u at the foci S and S’, respectively, where PS=r. The coordinate of the point P is p(t).
By the geometry of the figure, we get that $p(t) = [ae+ rcos(t) , rsin(t)]$
$\dfrac{\left (ae+rcos(t) \right )^{2}}{a^{2}}+\dfrac{\left ( rsint \right )^{2}}{b^{2}} =1$
$ b^{2}a^{2}e^{2}+b^{2}r^{2}cos^{2}t + 2ab^{2}ercos(t) + a^{2}r^{2}sin^{2}t-b^{2}a^{2}=0$
Simplifying we get the following.
$(a^{2}sin^{2}t + b^{2}cos^{2}t)r^{2} +2ab^{2}ecos(t)-b^{4} =0$ (as we know $b^{2}=a^{2}(1-e^{2})$)
Solving this equation, we get the two roots
$r_{1}=l_{1}, r_{2}=-l_{2} $
$ \left | l_{1} + l_{2}\right |=\left | r_{1}-r_{2} \right | =\sqrt{\left ( r_{1}+r_{2} \right )^{2}-4r_{1}r_{2}}$
$\left | l_{1}+l_{2} \right |=\sqrt{\left ( \dfrac{2abecos(t)}{a^{2}sin^{2}t + b^{2}cos^{2}t} \right )^{2}+ \dfrac{4b^{4}}{a^{2}sin^{2}t + b^{2}cos^{2}t}}$
Simplifying the above expression, we get the following.
$ \left | l_{1}+l_{2} \right |= \dfrac{2b^{2}}{a^{2}sin^{2}t +b^{2}cos^{2}t} \sqrt{a^{2}e^{2}cos^{2}t + a^{2}sin^{2}t + b^{2}cos^{2}t}$
Now substituting $b^{2}=a^{2}(1-e^{2})$ , we get the following.
$\left | l_{1}+l_{2} \right |=\dfrac{2b^{2}}{a^{2}sin^{2}t +b^{2}cos^{2}t} \sqrt{a^{2}e^{2}cos^{2}t + a^{2}sin^{2}t + a^{2}cos^{2}t - a^{2}e^{2}cos^{2}t }$
So we get length of focal chord PQ $= \dfrac{2ab^{2}}{a^{2}sin^{2}t +b^{2}cos^{2}t }$
Hence, the length of the focal chord of the ellipse $ \dfrac{x^{2}}{a^{2}} + \dfrac{y^{2}}{b^{2}} =1$ which is inclined to the major axis at a given angle θ is $\dfrac{2ab^{2}}{a^{2}sin^{2}\theta +b^{2}cos^{2}\theta }$.
Interesting Facts
The eccentricity of the ellipse will always be between 0 to 1.
An ellipse is created by a plane intersecting a double-napped right cone at some angle of its base.
The ratio of the focal length to the length of the semi-major axis of the ellipse is defined as the ellipse's eccentricity.
Solved Examples
1. Find the sum of the focal distances of a point on the ellipse $\dfrac{x^{2}}{4} + \dfrac{y^{2}}{16} =1$.
Ans: It is evident that the sum of focal distances from the point of an ellipse is 2a, where a is the length of the major axis.
For the given ellipse equation, the semi-major axis length is 4 units.
So, the sum of the focal distances of a point on the ellipse will be $= 2 \times 4 = 8 units$.
2. Find the sum of the distances of any point on the ellipse $9x^{2} + 4y^{2} =36$ from its foci.
Ans: As we know, the sum of the distances to any point on the ellipse(x,y) from the foci is equal to twice the length of the major axis.
$9x^{2} + 4y^{2} =36$
$ \dfrac{x^{2}}{4} + \dfrac{y^{2}}{9} =1 $
Comparing with the general equation of an ellipse
$ \dfrac{x^{2}}{b^{2}} + \dfrac{y^{2}}{a^{2}} =1$ with the given equation
$ \dfrac{x^{2}}{4} + \dfrac{y^{2}}{9} =1 $,
we get the length of the major axis a = 3.
Therefore, the sum of the distances of any point on the ellipse is equal to the length of the major axis $= 2 \times 3 = 6$.
3. Let P be the point on the ellipse having (3,4) and (3,−2) as the ends of the minor axis. If the sum of the focal distances of P is given equally to 10 then find the equation of an ellipse.
Ans: Endpoints of minor axis P=(3,4) and Q=(3,−2)
The Centre of an ellipse is the midpoint of PQ=(3,1)
Length PQ
$=2b=\sqrt{(-2-4)^{2}}=6$
$b=3$
Sum of the focal distance of =2a=10
$a=5$
Therefore equation of ellipse is $\dfrac{(x-3)^{2}}{25} + \dfrac{(y-1)^{2}}{9} =1$
4. What will be the sum of the distances of any point on the ellipse $\dfrac{x^{2}}{16} + \dfrac{y^{2}}{25} =1$ from its foci?
Ans: As we know, the Sum of the distances to any point on the ellipse(x,y) from the foci is twice the length of the major axis.
$\dfrac{x^{2}}{16} + \dfrac{y^{2}}{25} =1$
Comparing with the general equation of an ellipse
$\dfrac{x^{2}}{a^{2}} + \dfrac{y^{2}}{b^{2}} =1$
$\dfrac{x^{2}}{16} + \dfrac{y^{2}}{25} =1 $
We get the length of the major axis, b = 5.
Therefore the sum of the distances of any point on the ellipse = 2 \times 5 = 10.
5. Which is the equation of the ellipse with its axes equal to 5cm and 2cm, respectively?
Ans. The equation of the ellipse with its axes equal to 5cm and 2cm, respectively, is the following.
$\dfrac{x^{2}}{25} + \dfrac{y^{2}}{4} =1$
Summary
There are two axes of symmetry for the ellipse.
The foci of an ellipse always lie on the ellipse's major axis.
The focal chord passes through any focus of the ellipse.
The sum of the focal distance of any point on an ellipse is constant and equal to the length of the ellipse's major axis.
Practice Problems
1. Which is the equation of the ellipse with one of its axes twice the other?
2. Find the equation of the ellipse with its axes equal to each other.
3. Find the length of the axes from the equation $\dfrac{x^{2}}{25} + \dfrac{y^{2}}{4} =1$.
FAQs on Focal Distance of Ellipse
1. What is meant by the focal distance of an ellipse?
The focal distance of an ellipse refers to the distance from any point P(x, y) on the ellipse's perimeter to one of its two foci. Since an ellipse has two foci, typically denoted as F₁ and F₂, every point on the ellipse has two focal distances, which are the lengths of the segments PF₁ and PF₂.
2. What is the significance of the sum of focal distances for any point on an ellipse?
The most fundamental property of an ellipse is that the sum of the two focal distances for any point on its curve is constant. This constant sum is always equal to the length of the ellipse's major axis (2a). This property, PF₁ + PF₂ = 2a, is what defines the shape of the ellipse.
3. How do you calculate the two focal distances of a point on an ellipse?
For a standard horizontal ellipse with the equation x²/a² + y²/b² = 1, the focal distances for any point P(x, y) on it can be calculated using its eccentricity 'e'. The formulas are:
- Distance to one focus (PF₁) = a + ex
- Distance to the other focus (PF₂) = a - ex
4. How is the distance between the two foci of an ellipse determined?
The distance between the two foci (F₁ and F₂) of an ellipse is given by 2c. The value of 'c' is the distance from the center of the ellipse to one focus. It is calculated using the relationship between the semi-major axis (a) and the semi-minor axis (b): c² = a² - b². Therefore, the distance between the foci is 2√(a² - b²).
5. Why is the sum of the focal distances of an ellipse always equal to the length of the major axis (2a)?
This can be understood by considering a point at one of the vertices of the major axis, for instance, V(a, 0). The foci are at F₁(-c, 0) and F₂(c, 0). The distance from V to F₁ is a - (-c) = a + c. The distance from V to F₂ is a - c. The sum of these distances is (a + c) + (a - c) = 2a. Since the definition of an ellipse states this sum must be constant for all points on its curve, this value must hold true for every point.
6. How does the concept of focal distance in an ellipse differ from that in a parabola or a hyperbola?
The key difference lies in the defining property of each conic section related to their foci:
- Ellipse: The sum of the distances from any point to two fixed foci is constant (PF₁ + PF₂ = constant).
- Hyperbola: The difference between the distances from any point to two fixed foci is constant (|PF₁ - PF₂| = constant).
- Parabola: It has only one focus. The distance from any point to the focus is equal to its perpendicular distance to a fixed line called the directrix.
7. Are there any real-world applications where the focal distance of an ellipse is important?
Yes, the focal properties of an ellipse are used in various fields:
- Astronomy: Planets travel in elliptical orbits with the Sun at one focus. The changing focal distance between the planet and the Sun affects its orbital speed.
- Acoustics: In 'whispering galleries' with elliptical ceilings, a sound made at one focus is clearly heard at the other focus, as sound waves reflect off the walls and converge there.
- Medicine: In a procedure called lithotripsy, powerful shockwaves are generated at one focus of an elliptical reflector to break up kidney stones positioned at the other focus without surgery.
8. Does the focal distance calculation change if the ellipse is vertical instead of horizontal?
Yes, while the underlying principle (PF₁ + PF₂ = 2a) remains the same, the specific formulas for calculating the two focal distances adapt to the orientation. For a vertical ellipse with the equation x²/b² + y²/a² = 1, the foci are on the y-axis. The formulas for the focal distances of a point P(x, y) become PF₁ = a + ey and PF₂ = a - ey, using the y-coordinate instead of the x-coordinate.
