Wednesday, August 13, 2025

24.2 - Solved Examples on Area bounded by Curve and Line

In the previous section, we saw area bounded by a curve and a line. We saw some solved examples also. In this section, we will see some solved examples related to the topics that we discussed so far in this chapter.

Solved example 24.8
Find the area of the region bounded by the ellipse $\small{\frac{x^2}{16}~+~\frac{y^2}{9}~=~1}$.
Solution:
1. First we write the given equation in the form: y = f(x)
$\small{\frac{x^2}{16}~+~ \frac{y^2}{9}~=~1}$

$\small{\Rightarrow \frac{y^2}{9}~=~1~-~\frac{x^2}{16}}$

$\small{\Rightarrow y^2~=~9 \left(1~-~\frac{x^2}{16} \right)~=~9 \left(\frac{16~-~x^2}{16} \right)~=~\frac{9}{16}\left(16~-~x^2 \right)}$

$\small{\Rightarrow y~=~f(x)~=~\pm \frac{3}{4} \sqrt{4^2~-~x^2}}$

• In the above equation, if we input all x values from the interval [−4,4], we will get the ordered pairs, which when plotted, will give the red ellipse in fig.24.12 below:

Fig.24.12

2. In the fig.24.12, we want the area of the portion shaded in violet color. This portion is named as OABOA.

• The portion shaded in violet color is bounded by four items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = 0 (y-axis)
    ♦ The horizontal line y=0 (x-axis)

• Consider the thin vertical strip of width dx. This strip is situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

Therefore, area (A) of the violet portion can be obtained as:
$\small{A~=~\int_0^4{\left[f(x) \right]dx}~=~\int_0^4{\left[\frac{3}{4} \sqrt{4^2~-~x^2} \right]dx}}$

• Here we discard $\small{f(x)~=~-\frac{3}{4} \sqrt{4^2~-~x^2}}$  and take $\small{f(x)~=~+\frac{3}{4} \sqrt{4^2~-~x^2}}$. This is because, OABOA is in the first quadrant. In this quadrant, all y values are +ve.

3. This integration can be done as shown below:

• First we find the indefinite integral F:

$\small{F~=~\frac{3}{4} \int{\left[\sqrt{4^2~-~x^2} \right]dx}}$

• This is a standard integral (see section 23.19). We have:

$\small{F~=~\int{\left[\sqrt{a^2~-~x^2} \right]dx}~=~\frac{x}{2} \sqrt{a^2~-~x^2}~+~\frac{a^2}{2} \sin^{-1}\frac{x}{a}}$
Therefore, $\small{A~=~\left[\frac{x}{2} \sqrt{4^2~-~x^2}~+~\frac{4^2}{2} \sin^{-1}\frac{x}{4} \right]_0^{4}}$

$\small{~=~\frac{3}{4} \left[\frac{4}{2} \sqrt{4^2~-~4^2}~+~\frac{4^2}{2} \sin^{-1}\frac{4}{4} \right]~-~\frac{3}{4} \left[\frac{0}{2} \sqrt{4^2~-~0^2}~+~\frac{4^2}{2} \sin^{-1}\frac{0}{4} \right]}$

$\small{~=~\frac{3}{4} \left[0~+~8 \sin^{-1}1 \right]~-~\frac{3}{4} \left[0~+~\frac{4^2}{2} \sin^{-1}0 \right]}$

$\small{~=~\frac{3}{4} \left[8 \left(\frac{\pi}{2} \right) \right]~-~\frac{b}{a} \left[0~+~0 \right]~=~3 \pi}$

4. In the fig.24.12 above, we see that, the ellipse is symmetrical about both x and y axes. So the total area of the ellipse is four times the area of OABOA.

• We can write:
Whole area enclosed by the ellipse
$\small{~=~(4)(3) \pi~=~12 \pi}$

Alternate method:

1. In a previous section of this chapter, we derived the formula for area of the ellipse. See solved example 24.2.
• We saw that:
Area enclosed by the ellipse $\small{\frac{x^2}{a^2}~+~\frac{y^2}{b^2}~=~1}$ is $\small{\pi a b}$.

2. In our present case, a = 4 and b = 3.
So we get:
Area = $\small{\pi (4) (3)~=~12 \pi}$

Solved example 24.9
Find the area of the region bounded by the ellipse $\small{\frac{x^2}{4}~+~\frac{y^2}{9}~=~1}$.
Solution:
1. First we write the given equation in the form: y = f(x)
$\small{\frac{x^2}{4}~+~ \frac{y^2}{9}~=~1}$

$\small{\Rightarrow \frac{y^2}{9}~=~1~-~\frac{x^2}{4}}$

$\small{\Rightarrow y^2~=~9 \left(1~-~\frac{x^2}{4} \right)~=~9 \left(\frac{4~-~x^2}{4} \right)~=~\frac{9}{4}\left(4~-~x^2 \right)}$

$\small{\Rightarrow y~=~f(x)~=~\pm \frac{9}{4} \sqrt{2^2~-~x^2}}$

• In the above equation, if we input all x values from the interval [−2,2], we will get the ordered pairs, which when plotted, will give the red ellipse in fig.24.13 below:

Fig.24.13

2. In the fig.24.13, we want the area of the portion shaded in violet color. This portion is named as OABOA.

• The portion shaded in violet color is bounded by four items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = 0 (y-axis)
    ♦ The horizontal line y=0 (x-axis)

• Consider the thin vertical strip of width dx. This strip is situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

Therefore, area (A) of the violet portion can be obtained as:
$\small{A~=~\int_0^2{\left[f(x) \right]dx}~=~\int_0^2{\left[\frac{3}{2} \sqrt{2^2~-~x^2} \right]dx}}$

• Here we discard $\small{f(x)~=~-\frac{3}{2} \sqrt{2^2~-~x^2}}$  and take $\small{f(x)~=~+\frac{3}{2} \sqrt{2^2~-~x^2}}$. This is because, OABOA is in the first quadrant. In this quadrant, all y values are +ve.

3. This integration can be done as shown below:

• First we find the indefinite integral F:

$\small{F~=~\frac{3}{2} \int{\left[\sqrt{2^2~-~x^2} \right]dx}}$

• This is a standard integral (see section 23.19). We have:

$\small{F~=~\int{\left[\sqrt{a^2~-~x^2} \right]dx}~=~\frac{x}{2} \sqrt{a^2~-~x^2}~+~\frac{a^2}{2} \sin^{-1}\frac{x}{a}}$
Therefore, $\small{A~=~\left[\frac{x}{2} \sqrt{2^2~-~x^2}~+~\frac{2^2}{2} \sin^{-1}\frac{x}{2} \right]_0^{2}}$

$\small{~=~\frac{3}{2} \left[\frac{2}{2} \sqrt{2^2~-~2^2}~+~\frac{2^2}{2} \sin^{-1}\frac{2}{2} \right]~-~\frac{3}{2} \left[\frac{0}{2} \sqrt{2^2~-~0^2}~+~\frac{2^2}{2} \sin^{-1}\frac{0}{2} \right]}$

$\small{~=~\frac{3}{2} \left[0~+~2 \sin^{-1}1 \right]~-~\frac{3}{2} \left[0~+~2 \sin^{-1}0 \right]}$

$\small{~=~\frac{3}{2} \left[2 \left(\frac{\pi}{2} \right) \right]~-~\frac{b}{a} \left[0~+~0 \right]~=~\frac{3 \pi}{2}}$

4. In the fig.24.13 above, we see that, the ellipse is symmetrical about both x and y axes. So the total area of the ellipse is four times the area of OABOA.

• We can write:
Whole area enclosed by the ellipse
$\small{~=~(4)\frac{3 \pi}{2}~=~6 \pi}$

Alternate method:

1. In a previous section of this chapter, we derived the formula for area of the ellipse. See solved example 24.2.
• We saw that:
Area enclosed by the ellipse $\small{\frac{x^2}{a^2}~+~\frac{y^2}{b^2}~=~1}$ is $\small{\pi a b}$.

2. In our present case, a = 2 and b = 3.
So we get:
Area = $\small{\pi (2) (3)~=~6 \pi}$

Solved example 24.10
Find the area of the region bounded by the line y = 3x + 2, the x-axis and the ordinates x = −1 and x = 1
Solution:
1. First we write the given equations in the form: y = f(x)
But it is already in this form. $\small{y~=~f(x)~=~3x+2}$

2. We are asked to find the area bounded by four items:

    ♦ The line y = f(x)
    ♦ The vertical line x = −1
    ♦ The vertical line x = 1
    ♦ The horizontal line y=0 (x-axis)
    
• So we want the area $\small{\left(A_1 + A_2 \right)}$ in fig.24.14 below. Recall that, area below the x-axis will be calculated with a −ve sign. This is the reason why, we split the region into A1 and A2.
   ♦ A1 is shaded in magenta color. It is named as EAD
   ♦ A2 is shaded in yellow color. It is named as ABC

Fig.24.14

• Solving the equations of f(x) and the x-axis, we get:
x = −(2/3) and y = 0
So the red line  intersect the x-axis at [−(2/3),0]. This is the point A in fig.24.14

3. First we will find the area of the magenta region.   
• The magenta region is bounded by three items:
    ♦ The line y = f(x)
    ♦ The vertical line x = −1
    ♦ The horizontal line y=0 (x-axis)

• Assume a thin vertical strip of width dx, situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

Therefore, area (A1) of the magenta portion can be obtained as:
$\small{A_1~=~\int_{-1}^{-2/3}{\left[f(x) \right]dx}~=~\int_{-1}^{-2/3}{\left[3x+2 \right]dx}}$

• This integration can be done as shown below:

(i) First we find the indefinite integral F1:

$\small{F_1~=~\int{\left[3x+2 \right]dx}~=~\frac{3x^2}{2}~+~2x}$

(ii) Therefore, $\small{A_1~=~\left[\frac{3x^2}{2}~+~2x \right]_{-1}^{-2/3}}$

$\small{~=~\left[\frac{3}{2}\left(\frac{4}{9} \right)~+~2\left(\frac{-2}{3} \right) \right]~-~\left[\frac{3(-1)^2}{2}~+~2(-1) \right]}$

$\small{~=~\left[\frac{2}{3}~-~\frac{4}{3} \right]~-~\left[\frac{3}{2}~-~2 \right]~=~\left[\frac{-2}{3} \right]~-~\left[\frac{-1}{2} \right]}$

$\small{~=~\left[\frac{-2}{3} \right]~+~\left[\frac{1}{2} \right]~=~\frac{-1}{6}}$

• Area can not be −ve. We must take the absolute value. We can write:
$\small{A_1~=~\left| \frac{-1}{6}  \right|~=~\frac{1}{6}}$

4. Next we will find the area of the yellow region.   
• The yellow region is bounded by three items:
    ♦ The line y = f(x)
    ♦ The vertical line x = 1
    ♦ The horizontal line y=0 (x-axis)

• Assume a thin vertical strip of width dx, situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

• Therefore, area (A2) of the yellow portion can be obtained as:
$\small{A_2~=~\int_{-2/3}^1{\left[f(x) \right]dx}~=~\int_{-2/3}^1{\left[3x+2 \right]dx}}$

• This integration can be done as shown below:

(i) First we find the indefinite integral F1:

$\small{F_1~=~\int{\left[3x+2 \right]dx}~=~\frac{3x^2}{2}~+~2x}$

(ii) Therefore, $\small{A_2~=~\left[\frac{3x^2}{2}~+~2x \right]_{-2/3}^1}$

$\small{~=~\left[\frac{3(1)^2}{2}~+~2(1) \right]~-~\left[\frac{3}{2}\left(\frac{4}{9} \right)~+~2\left(\frac{-2}{3} \right) \right]}$

$\small{~=~\left[\frac{7}{2} \right]~-~\left[\frac{2}{3}~-~\frac{4}{3} \right]~=~\left[\frac{7}{2} \right]~-~\left[\frac{-2}{3} \right]~=~\frac{25}{6}}$

5. So from (3) and (4), we get:
Required area = $\small{A_1~+~A_2}$
$\small{~=~\frac{1}{6} + \frac{25}{6}~=~\frac{26}{6}~=~\frac{13}{3}}$ sq.units

Solved example 24.11
Find the area of the region bounded by the curve y = cos x between x = 0 and x = 2π.
Solution:
1. First we write the given equations in the form: y = f(x)
But it is already in this form. $\small{y~=~f(x)~=~\cos x}$

2. We are asked to find the area bounded by four items:

    ♦ The curve y = f(x)
    ♦ The vertical line x = 0
    ♦ The vertical line x = 2π
    
• So we want the area $\small{\left(A_1 + A_2 + A_3 \right)}$ in fig.24.15 below. Recall that, area below the x-axis will be calculated with a −ve sign. This is the reason why, we split the region into A1, A2and A3.
   ♦ A1 is shaded in yellow color. It is named as OBA
   ♦ A2 is shaded in magenta color. It is named as BCD
   ♦ A3 is shaded in green color. It is named as DEF

Fig.24.15

• Solving the equations of f(x) and the x-axis, we get:
cos x = 0 ⇒ x = π/2 and x = 3π/2

So the red curve  intersect the x-axis at (π/2,0) and (3π/2,0). These are the point B and D in fig.24.14

3. First we will find the area of the yellow region.   
• The yellow region is bounded by three items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = 0 (y-axis)
    ♦ The horizontal line y=0 (x-axis)

• Assume a thin vertical strip of width dx, situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

• Therefore, area (A1) of the yellow portion can be obtained as:
$\small{A_1~=~\int_{0}^{\pi/2}{\left[f(x) \right]dx}~=~\int_{0}^{\pi/2}{\left[\cos x \right]dx}}$

• This integration can be done as shown below:

(i) First we find the indefinite integral F1:

$\small{F_1~=~\int{\left[\cos x \right]dx}~=~\sin x}$

(ii) Therefore, $\small{A_1~=~\left[\sin x \right]_{0}^{\pi/2}}$

$\small{~=~\left[1 \right]~-~\left[0 \right]~=~1}$ sq.unit

4. Next we will find the area of the magenta region.   
• The magenta region is bounded by two items:
    ♦ The curve y = f(x)
    ♦ The horizontal line y=0 (x-axis)

• Assume a thin vertical strip of width dx, situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

Therefore, area (A2) of the magenta portion can be obtained as:
$\small{A_2~=~\int_{\pi/2}^{3\pi/2}{\left[f(x) \right]dx}~=~\int_{\pi/2}^{3\pi/2}{\left[\cos x \right]dx}}$

• This integration can be done as shown below:

(i) First we find the indefinite integral F1:

$\small{F_2~=~\int{\left[\cos x \right]dx}~=~\sin x}$

(ii) Therefore, $\small{A_1~=~\left[\sin x \right]_{\pi/2}^{3\pi/2}}$

$\small{~=~\left[-1 \right]~-~\left[1 \right]~=~-2}$

• Area can not be −ve. We must take the absolute value. We can write:
$\small{A_2~=~\left| -2  \right|~=~2}$ sq.units

5. Finally, we will find the area of the green region.   
• The green region is bounded by three items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = 2π
    ♦ The horizontal line y = 0 (x-axis)

• Assume a thin vertical strip of width dx, situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

• Therefore, area (A3) of the green portion can be obtained as:
$\small{A_3~=~\int_{3\pi/2}^{2\pi}{\left[f(x) \right]dx}~=~\int_{3\pi/2}^{2\pi}{\left[\cos x \right]dx}}$

• This integration can be done as shown below:

(i) First we find the indefinite integral F3:

$\small{F_3~=~\int{\left[\cos x \right]dx}~=~\sin x}$

(ii) Therefore, $\small{A_3~=~\left[\sin x \right]_{3\pi/2}^{2\pi}}$

$\small{~=~\left[0 \right]~-~\left[-1 \right]~=~1}$ sq.unit

6. So from (3), (4) and (5), we get:
Required area = $\small{A_1~+~A_2~+~A_3}$
= 1 + 2 + 1 = 4 sq.units


The link below gives a few more solved examples:

Exercise 24.1


In the next section, we will see area between two curves.

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Monday, August 11, 2025

24.1 - Area of a Region Bounded by a Curve and a Line

In the previous section, we saw area under simple curves. In this section, we will see area bounded by a curve and a line.

The following solved example will help us to understand the basic details about the method:

Solved example 24.3
Find the area of the region bounded by the curve $\small{y~=~x^2}$ and the line $\small{y = 4}$
Solution:
1. First we write the given equations in the form: y = f(x) and y = g(x).
But they are already in those forms:

$\small{y~=~f(x)~=~x^2}$

$\small{y~=~g(x)~=~4}$

• They are plotted in the fig.24.7 below:

Fig.24.7

2. Consider fig.24.7(a) above. Solving y = f(x) and y = g(x), we get: x = 2 and x = −2. So we want the area of the portion shaded in violet color. This portion is named as OABOA.

• The portion shaded in violet color is bounded by four items:
    ♦ The curve y = f(x)
    ♦ The line y = g(x)
    ♦ The vertical line x = 2
    ♦ vertical line x = 0 (y-axis)

• Consider the thin vertical strip of width dx. This strip is situated at a distance of x from O.
• So y-cordinate of the lower end of the strip will be f(x). And the y-cordinate of the upper end of the strip will be g(x).
• Consequently, the height of the strip will be [g(x) − f(x)]
• So area of the strip will be:
$\small{\left[g(x)~-~f(x) \right]dx~=~\left[4~-~x^2 \right]dx}$

Therefore, area (A) of the violet portion can be obtained as:
$\small{A~=~\int_0^2{\left[4~-~x^2 \right]dx}}$

3. This integration can be done as shown below:

• First we find the indefinite integral F:

$\small{F~=~\int{\left[4~-~x^2 \right]dx}~=~4x~-~\frac{x^3}{3}}$

Therefore, $\small{A~=~\left[4x~-~\frac{x^3}{3} \right]_0^{2}}$

$\small{~=~ \left[4(2)~-~\frac{2^3}{3} \right]~-~\left[4(0)~-~\frac{0}{3} \right]}$

$\small{~=~ \left[8~-~\frac{8}{3} \right]~-~0~=~\frac{16}{3}}$

4. In the fig.24.7(a) above, we see that, f(x) is symmetrical about y axis. So the total area bounded by f'(x) and g(x) is two times the area of OABOA.

• We can write:
The required area
$\small{~=~(2)\frac{16}{3}~=~\frac{32}{3}}$

Alternate method:

1. First we write the equation of the curve in the form: x = f(y)

$\small{y~=~x^2}$

$\small{\Rightarrow x~=~f(y)~=~\pm \sqrt{y}}$

• It is the red parabola in fig.24.7 above.

2. Consider fig.24.7(b) above. We want the area of the portion shaded in violet color. This portion is named as OABOA.

• The portion shaded in violet color is bounded by four items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = 0 (y-axis)
    ♦ The horizontal line y = g(x)

• Consider the thin horizontal strip of thickness dy. This strip is situated at a distance of y from O. So length of the strip will be f(y). So area of the strip will be f(y) dy.

Therefore, area (A) of the violet portion can be obtained as:
$\small{A~=~\int_0^4{\left[f(y) \right]dy}~=~\int_0^4{\left[\sqrt{y} \right]dy}}$

• Here we discard $\small{x~=~f(y)~=~-\sqrt{y}}$  and take $\small{x~=~f(y)~=~\sqrt{y}}$. This is because, OABOA is in the first quadrant. In this quadrant, all x values are +ve.

3. This integration can be done as shown below:

• First we find the indefinite integral F:

$\small{F~=~\int{\left[\sqrt{y} \right]dy}~=~\frac{y^{3/2}}{3/2}~=~\frac{2\,y^{\frac{3}{2}}}{3}}$

Therefore, $\small{A~=~\left[\frac{2\,y^{\frac{3}{2}}}{3} \right]_0^{4}}$

$\small{~=~\left[\frac{2\,(4)^{\frac{3}{2}}}{3} \right]~-~\left[\frac{2\,(0)^{\frac{3}{2}}}{3} \right]~=~\frac{2^4}{3}~=~\frac{16}{3}}$

4. In the fig.24.7(a) above, we see that, f(x) is symmetrical about y axis. So the total area bounded by f'(x) and g(x) is two times the area of OABOA.

• We can write:
The required area
$\small{~=~(2)\frac{16}{3}~=~\frac{32}{3}}$

• We get the same result in both methods. From the examples that we saw so far, we can infer that, vertical strips and horizontal strips give the same result. So from now on wards, we will use only one type. Either vertical or horizontal. The choice depends on the type of problem.

Solved example 24.4
Find the area of the region in the first quadrant enclosed by the x-axis, the line y = x and the circle x2 + y2 = 32
Solution:
1. First we write the given equations in the form: y = f(x) and y = g(x)
$\small{x^2~+~ y^2~=~32}$

$\small{\Rightarrow y^2~=~32~-~x^2}$

$\small{\Rightarrow y~=~f(x)~=~\pm \sqrt{32~-~x^2}~=~\pm \sqrt{\left(4 \sqrt2 \right)^2~-~x^2}}$

• In the above equation, if we input all x values from the interval $\small{\left[-4 \sqrt2, 4 \sqrt2 \right]}$, we will get the ordered pairs, which when plotted, will give the red circle in fig.24.8 below.

• The equation y = x is already in the form $\small{y~=~g(x)~=~x}$

Fig.24.8

2. We are asked to find the area bounded by three items:

    ♦ The curve y = f(x)
    ♦ The line y = g(x)
    ♦ The horizontal line y=0 (x-axis)
    
In the problem, quadrant I is specially mentioned. So we want the area of the sector OABOA

• Solving the equations of f(x) and the x-axis, we get:
x = 4√2 and y = 0
So the circle intersect the x-axis at (4√2,0). This is the point A in fig.24.8

• Solving the equations of f(x) and g(x), we get:
x = 4 and y = 4
So they intersect at (4,4). This is the point B in fig.24.8

3. Drop a perpendicular from B, on to the x-axis. Foot of this perpendicular is M.

• So the sector is now divided into two areas:
   ♦ OMBO (blue color)
   ♦ MABM (yellow color)
   
4. First we will find the area of the blue region.   
• The blue region is bounded by three items:
    ♦ The curve y = g(x)
    ♦ The vertical line x = 4
    ♦ The horizontal line y=0 (x-axis)

• Consider the thin vertical strip of width dx. This strip is situated at a distance of x from O. So height of the strip will be g(x). So area of the strip will be g(x) dx.

Therefore, area (A1) of the blue portion can be obtained as:
$\small{A_1~=~\int_0^4{\left[g(x) \right]dx}~=~\int_0^4{\left[x \right]dx}}$

• This integration can be done as shown below:

(i) First we find the indefinite integral F1:

$\small{F_1~=~\int{\left[x \right]dx}~=~\frac{x^2}{2}}$

(ii) Therefore, $\small{A_1~=~\left[\frac{x^2}{2} \right]_0^{4}~=~\frac{16}{2}~=~8}$

5. Next we will find the area of the yellow region.   
• The yellow region is bounded by three items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = 4
    ♦ The horizontal line y=0 (x-axis)

• Consider the thin vertical strip of width dx. This strip is situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

Therefore, area (A2) of the blue portion can be obtained as:
$\small{A_2~=~\int_4^{4 \sqrt2}{\left[f(x) \right]dx}~=~\int_4^{4 \sqrt2}{\left[\sqrt{\left(4 \sqrt2 \right)^2~-~x^2} \right]dx}}$

• Here we discard $\small{f(x)~=~-\sqrt{\left(4 \sqrt2 \right)^2~-~x^2}}$  and take $\small{f(x)~=~+\sqrt{\left(4 \sqrt2 \right)^2~-~x^2}}$. This is because, yellow region is in the first quadrant. In this quadrant, all y values are +ve.

• This integration can be done as shown below:

(i) First we find the indefinite integral F2:

$\small{F_2~=~\int{\left[\sqrt{\left(4 \sqrt2 \right)^2~-~x^2} \right]dx}}$

• This is a standard integral (see section 23.19). We get:

$\small{F_2~=~\int{\left[\sqrt{\left(4 \sqrt2 \right)^2~-~x^2} \right]dx}}$

$\small{~=~\frac{x}{2} \sqrt{\left(4 \sqrt2 \right)^2~-~x^2}~+~\frac{\left(4 \sqrt2 \right)^2}{2} \sin^{-1}\frac{x}{4 \sqrt2}}$

(ii) Therefore, $\small{A_2~=~\left[\frac{x}{2} \sqrt{\left(4 \sqrt2 \right)^2~-~x^2}~+~\frac{\left(4 \sqrt2 \right)^2}{2} \sin^{-1}\frac{x}{4 \sqrt2} \right]_4^{4 \sqrt2}}$

$\small{~=~ \left[\frac{\left(4 \sqrt2 \right)}{2} \sqrt{\left(4 \sqrt2 \right)^2~-~\left(4 \sqrt2 \right)^2}~+~\frac{\left(4 \sqrt2 \right)^2}{2} \sin^{-1}\frac{\left(4 \sqrt2 \right)}{4 \sqrt2} \right]}$

$\small{~~~~~~~~~-~ \left[\frac{4}{2} \sqrt{\left(4 \sqrt2 \right)^2~-~4^2}~+~\frac{\left(4 \sqrt2 \right)^2}{2} \sin^{-1}\frac{4}{4 \sqrt2} \right]}$

$\small{~=~ \left[\frac{\left(4 \sqrt2 \right)}{2} \sqrt{0}~+~16 \sin^{-1}(1) \right]~-~ \left[\frac{4}{2} \sqrt{16}~+~16 \sin^{-1}\frac{1}{\sqrt2} \right]}$

$\small{~=~ \left[\frac{16\,\pi}{2} \right]~-~ \left[8~+~\frac{16\,\pi}{4} \right]~=~8 \pi~-~8~-~4 \pi~=~4 \pi~-~8}$

6. So from (4) and (5), we get:
Required area = $\small{A_1~+~A_2}$
$\small{~=~8 + 4\pi-8~=~4 \pi}$

Solved example 24.5
Find the area bounded by the ellipse $\small{\frac{x^2}{a^2}~+~\frac{y^2}{b^2}~=~1}$ and the ordinates x = 0 and x = ae, where, $\small{b^2~=~a^2(1 - e^2)}$ and $\small{e<1}$.
Solution:
1. First we write the given equation in the form: y = f(x)
$\small{\frac{x^2}{a^2}~+~ \frac{y^2}{b^2}~=~1}$

$\small{\Rightarrow \frac{y^2}{b^2}~=~1~-~\frac{x^2}{a^2}}$

$\small{\Rightarrow y^2~=~b^2 \left(1~-~\frac{x^2}{a^2} \right)~=~b^2 \left(\frac{a^2~-~x^2}{a^2} \right)~=~\frac{b^2}{a^2}\left(a^2~-~x^2 \right)}$

$\small{\Rightarrow y~=~f(x)~=~\pm \frac{b}{a} \sqrt{a^2~-~x^2}}$

• In the above equation, if we input all x values from the interval [−a,a], we will get the ordered pairs, which when plotted, will give the red ellipse in fig.24.9 below:

Fig.24.9

2. Consider fig.24.9 above. We want the area of the portion shaded in violet color. This portion is named as OABCO.

Given that: $\small{b^2~=~a^2(1-e^2)}$
$\small{\Rightarrow 1 - e^2~=~\frac{b^2}{a^2}}$
$\small{\Rightarrow e^2~=~1 - \frac{b^2}{a^2}}$
So e is a constant.

• The portion shaded in violet color is bounded by four items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = 0 (y-axis)
    ♦ The vertical line x = ae
    ♦ The horizontal line y=0 (x-axis)

• Consider the thin vertical strip of width dx. This strip is situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

Therefore, area (A) of the violet portion can be obtained as:
$\small{A~=~\int_0^{ae}{\left[f(x) \right]dx}~=~\int_0^{ae}{\left[\frac{b}{a} \sqrt{a^2~-~x^2} \right]dx}}$

• Here we discard $\small{f(x)~=~-\frac{b}{a} \sqrt{a^2~-~x^2}}$  and take $\small{f(x)~=~+\frac{b}{a} \sqrt{a^2~-~x^2}}$. This is because, OABOA is in the first quadrant. In this quadrant, all y values are +ve.

3. This integration can be done as shown below:

• First we find the indefinite integral F:

$\small{F~=~\frac{b}{a} \int{\left[\sqrt{a^2~-~x^2} \right]dx}}$

• This is a standard integral (see section 23.19). We have:

$\small{F~=~\int{\left[\sqrt{a^2~-~x^2} \right]dx}~=~\frac{x}{2} \sqrt{a^2~-~x^2}~+~\frac{a^2}{2} \sin^{-1}\frac{x}{a}}$
Therefore, $\small{A~=~\left[\frac{x}{2} \sqrt{a^2~-~x^2}~+~\frac{a^2}{2} \sin^{-1}\frac{x}{a} \right]_0^{ae}}$

$\small{~=~\frac{b}{a} \left[\frac{a}{2} \sqrt{a^2~-~a^2e^2}~+~\frac{a^2}{2} \sin^{-1}\frac{ae}{a} \right]~-~\frac{b}{a} \left[\frac{0}{2} \sqrt{a^2~-~0^2}~+~\frac{a^2}{2} \sin^{-1}\frac{0}{a} \right]}$

$\small{~=~\frac{b}{a} \left[\frac{a}{2} \sqrt{a^2(1~-~e^2)}~+~\frac{a^2}{2} \sin^{-1}e \right]~-~\frac{b}{a} \left[0~+~\frac{a^2}{2} \sin^{-1}0 \right]}$

$\small{~=~\frac{b}{a} \left[\frac{a^2}{2} \sqrt{1~-~e^2}~+~\frac{a^2}{2} \sin^{-1}e \right]~-~\frac{b}{a} \left[0~+~0 \right]}$

$\small{~=~\frac{a^2 b}{2a} \left[ \sqrt{1~-~e^2}~+~ \sin^{-1}e \right]~-~\frac{b}{a} \left[0 \right]}$

$\small{~=~\frac{ab}{2} \left[ \sqrt{1~-~e^2}~+~ \sin^{-1}e \right]}$

4. In the fig.24.9 above, we see that, the ellipse is symmetrical about the x axis. So the required area is two times the area of OABCO.

• We can write:
Required area
$\small{~=~(2)\frac{ab}{2} \left[ \sqrt{1~-~e^2}~+~ \sin^{-1}e \right]~=~ab \left[ \sqrt{1~-~e^2}~+~ \sin^{-1}e \right]}$

Solved example 24.6
Find the area bounded by the curve $\small{y^2~=~x}$ and the lines x = 1, x = 4 and the x-axis.
Solution:
1. First we write the given equation in the form: y = f(x)
$\small{y^2~=~x}$

$\small{\Rightarrow y~=~f(x)~=~\pm \sqrt{x}}$

• In the above equation, if we input all x values from the interval $\small{\left[0, \infty \right)}$, we will get the ordered pairs, which when plotted, will give the red parabola in fig.24.10 below.

Fig.24.10

2. We are asked to find the area bounded by four items:

    ♦ The curve y = f(x)
    ♦ The vertical line x = 1
    ♦ The vertical line x = 4
    ♦ The horizontal line y = 0 (x-axis)
    
• This area is marked as ABCDA in fig.21.10 above.

3. Consider the thin vertical strip of width dx. This strip is situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

Therefore, area of the violet portion can be obtained as:
$\small{A~=~\int_1^4{\left[f(x) \right]dx}~=~\int_1^4{\left[\sqrt{x} \right]dx}}$

• Here we discard $\small{f(x)~=~-\sqrt{x}}$  and take $\small{f(x)~=~+\sqrt{x}}$. This is because, violet region is in the first quadrant. In this quadrant, all y values are +ve.

• This integration can be done as shown below:

(i) First we find the indefinite integral F:

$\small{F~=~\int{\left[\sqrt{x} \right]dx}~=~\frac{2 x^{3/2}}{3}}$

(ii) Therefore, $\small{A~=~\left[\frac{2 x^{3/2}}{3} \right]_1^{4}}$

$\small{~=~ \left[\frac{2 (4)^{3/2}}{3} \right]~-~\left[\frac{2 (1)^{3/2}}{3} \right]}$

$\small{~=~ \left[\frac{16}{3} \right]~-~\left[\frac{2}{3} \right]~=~\frac{14}{3}}$ 

Solved example 24.7
Find the area of the region bounded by $\small{y^2~=~9x}$, x = 2, x = 4 and the x-axis.
Solution:
1. First we write the given equation in the form: y = f(x)
$\small{y^2~=~9x}$

$\small{\Rightarrow y~=~f(x)~=~\pm 3\sqrt{x}}$

• In the above equation, if we input all x values from the interval $\small{\left[0, \infty \right)}$, we will get the ordered pairs, which when plotted, will give the red parabola in fig.24.11 below.

Fig.24.11

2. We are asked to find the area bounded by four items:

    ♦ The curve y = f(x)
    ♦ The vertical line x = 2
    ♦ The vertical line x = 4
    ♦ The horizontal line y = 0 (x-axis)
    
This area is marked as ABCDA in fig.21.11 above.

3. Consider the thin vertical strip of width dx. This strip is situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

Therefore, area of the violet portion can be obtained as:
$\small{A~=~\int_2^4{\left[f(x) \right]dx}~=~\int_2^4{\left[3\sqrt{x} \right]dx}}$

• Here we discard $\small{f(x)~=~-3\sqrt{x}}$  and take $\small{f(x)~=~+3\sqrt{x}}$. This is because, violet region is in the first quadrant. In this quadrant, all y values are +ve.

• This integration can be done as shown below:

(i) First we find the indefinite integral F:

$\small{F~=~\int{\left[3\sqrt{x} \right]dx}~=~(3)\frac{2 x^{3/2}}{3}~=~2 x^{3/2}}$

(ii) Therefore, $\small{A~=~\left[2 x^{3/2} \right]_2^{4}}$

$\small{~=~ \left[2 (4)^{3/2} \right]~-~\left[2 (2)^{3/2} \right]}$

$\small{~=~ 16~-~4 \sqrt 2}$ 


In the next section, we will see a few solved examples related to the topics that we discussed so far in this chapter.

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Wednesday, July 30, 2025

Chapter 24 - Application of Integrals

In the previous section, we completed a discussion on integrals. In this chapter, we will see application of integrals.

Area under simple curves

One important application of integrals is the calculation of area under simple curves. Some basics about this application, can be written in steps:

1. In our earlier classes, we have seen the methods for finding areas of simple geometric figures like squares, rectangles, triangles, trapeziums etc.,  
• In those simple geometric figures, all sides are straight lines.

2. Now consider fig.24.1 below:

Fig.24.1

• AB, BC and CD are straight lines.
• But AD is a curve. AD is portion of the graph of the function $\small{f(x) = x^3 + 2x + 3}$
• In such a situation, we use integral calculus to find the area ABCDA.

3. Consider fig.24.2(a) below:

Fig.24.2

• Recall how we calculated the area bounded by the four items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = a
    ♦ The vertical line x = b
    ♦ The horizontal line y=0 (x-axis)
• We assumed that, the required area is composed of infinite number of very thin strips of width dx. The sum of the areas of all those infinite strips will give the required area. One such sample strip is shown in the fig.24.2(a).
• This sample strip is situated at a distance of ‘x’ from the origin. So height of this sample strip will be y=f(x). Consequently, area of this sample strip will be ydx, which is same as f(x) dx.
• Note that, since there are infinite strips, the width dx is infinitesimal.
• Area of the sample strip will be so small that, we denote the area as dA. So dA = f(x) dx.
• Symbolically, we denoted the sum of all the strips as: $\small{\int_a^b{\left[f(x) \right]dx}}$
• So we can write: $\small{A~=~\int_a^b{\left[f(x) \right]dx}~=~\int_a^b{\left[dA \right]}}$

4. Consider fig.24.2(b) above.
• Here also, the area is bounded by the same four items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = a
    ♦ The vertical line x = b
    ♦ The horizontal line y=0 (x-axis)
• We are tempted to apply the same equation: $\small{A~=~\int_a^b{\left[f(x) \right]dx}}$
But the calculated area will be −ve. We know that, area has no sign. So in such a situation, we must take the absolute value. We can write:
$\small{A~=~\left|\int_a^b{\left[f(x) \right]dx} \right|}$

5. Consider fig.24.3(a) below:

Fig.24.3

• The area is bounded by the four items:
    ♦ The curve x = g(x)
    ♦ The horizontal line y = c
    ♦ The horizontal line y = d
    ♦ The vertical line x=0 (y-axis)

• Here we can modify the equation that we saw in step (3) above. We get: $\small{A~=~\int_c^d{\left[g(y) \right]dy}~=~\int_c^d{\left[dA \right]}}$ 

6. Consider fig.24.3(b) above.
• Here we are tempted to apply the same equation as in step (5) above: $\small{A~=~\int_c^d{\left[g(y) \right]dy}}$
But the calculated area will be −ve. We know that, area has no sign. So in such a situation, we must take the absolute value. We can write:
$\small{A~=~\left|\int_c^d{\left[g(y) \right]dy} \right|}$

7. Consider fig.24.4 below:

Fig.24.4

• We want the area is bounded by the four items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = a
    ♦ The vertical line x = b
    ♦ The horizontal line y=0 (x-axis)

• Such an area is the sum of two areas:
   ♦ violet area (A1)
   ♦ yellow area (A2)
• If we use the equation $\small{A~=~\int_a^b{\left[f(x) \right]dx}}$, we will be getting $\small{-A_1~+~A_2}$
• Two avoid this error, we calculate A1 and A2 separately. Then we find the sum: A = |A1| + A2

Now we will see a solved example

Solved example 24.1
Find the area enclosed by the circle $\small{x^2~+~ y^2~=~a^2}$
Solution:
1. First we write the given equation in the form: y = f(x)
$\small{x^2~+~ y^2~=~a^2}$

$\small{\Rightarrow y^2~=~a^2~-~x^2}$

$\small{\Rightarrow y~=~f(x)~=~\pm \sqrt{a^2~-~x^2}}$

• In the above equation, if we input all x values from the interval [−a,a], we will get the ordered pairs, which when plotted, will give the red circle in fig.24.5 below:

Fig.24.5

2. Consider fig.24.5(a) above. We want the area of the portion shaded in violet color. This portion is named as OABOA.

• The portion shaded in violet color is bounded by four items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = 0 (y-axis)
    ♦ The vertical line x = a
    ♦ The horizontal line y=0 (x-axis)

• Consider the thin vertical strip of width dx. This strip is situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

Therefore, area (A) of the violet portion can be obtained as:
$\small{A~=~\int_0^a{\left[f(x) \right]dx}~=~\int_0^a{\left[\sqrt{a^2~-~x^2} \right]dx}}$

• Here we discard $\small{f(x)~=~-\sqrt{a^2~-~x^2}}$  and take $\small{f(x)~=~+\sqrt{a^2~-~x^2}}$. This is because, OABOA is in the first quadrant. In this quadrant, all y values are +ve.

3. This integration can be done as shown below:

• First we find the indefinite integral F:

$\small{F~=~\int{\left[\sqrt{a^2~-~x^2} \right]dx}}$

• This is a standard integral (see section 23.19). We have:

$\small{F~=~\int{\left[\sqrt{a^2~-~x^2} \right]dx}~=~\frac{x}{2} \sqrt{a^2~-~x^2}~+~\frac{a^2}{2} \sin^{-1}\frac{x}{a}}$

Therefore, $\small{A~=~\left[\frac{x}{2} \sqrt{a^2~-~x^2}~+~\frac{a^2}{2} \sin^{-1}\frac{x}{a} \right]_0^{a}}$

$\small{~=~\left[\frac{a}{2} \sqrt{a^2~-~a^2}~+~\frac{a^2}{2} \sin^{-1}\frac{a}{a} \right]~-~\left[\frac{0}{2} \sqrt{a^2~-~0^2}~+~\frac{a^2}{2} \sin^{-1}\frac{0}{a} \right]}$

$\small{~=~\left[0~+~\frac{a^2}{2} \sin^{-1}1 \right]~-~\left[0~+~\frac{a^2}{2} \sin^{-1}0 \right]}$

$\small{~=~\left[\frac{a^2}{2} \left(\frac{\pi}{2} \right) \right]~-~\left[0~+~0 \right]~=~\frac{\pi a^2}{4}}$

4. In the fig.24.5(a) above, we see that, the circle is symmetrical about both x and y axes. So the total area of the circle is four times the area of OABOA.

• We can write:
Whole area enclosed by the circle
$\small{~=~(4)\frac{\pi \,a^2}{4}~=~\pi\,a^2}$

• Note that, this result is in full agreement with the well known formula: Area of a circle = $\small{\pi r^2}$.
In our present case, the radius is 'a'. 

Alternate method:

1. First we write the given equation in the form: x = f(y)

$\small{x^2~+~ y^2~=~a^2}$

$\small{\Rightarrow x^2~=~a^2~-~y^2}$

$\small{\Rightarrow x~=~f(y)~=~\pm \sqrt{a^2~-~y^2}}$

• In the above equation, if we input all y values from the interval [−a,a], we will get the ordered pairs, which when plotted, will give the red circle in fig.24.5(a) and (b) above.

2. Consider fig.24.5(b) above. We want the area of the portion shaded in blue color. This portion is named as OBCOB.

• The portion shaded in blue color is bounded by four items:
    ♦ The curve x = f(y)
    ♦ The horizontal line y = 0 (x-axis)
    ♦ The horizontal line y = a
    ♦ The vertical line x = 0 (y-axis)
    
• Consider the thin horizontal strip of thickness dy. This strip is situated at a distance of y from O. So length of the strip will be f(y). So area of the strip will be f(y) dy.

Therefore, area (A) of the blue portion can be obtained as:
$\small{A~=~\int_0^a{\left[f(y) \right]dy}~=~\int_0^a{\left[-\sqrt{a^2~-~y^2} \right]dy}}$

• Here we discard $\small{x~=~f(y)~=~\sqrt{a^2~-~y^2}}$  and take $\small{x~=~f(y)~=~-\sqrt{a^2~-~y^2}}$. This is because, OBCOB is in the second quadrant. In this quadrant, all x values are −ve.

3. This integration can be done as shown below:

• First we find the indefinite integral F:

$\small{F~=~\int{\left[-\sqrt{a^2~-~y^2} \right]dy}~=~(-1)\int{\left[\sqrt{a^2~-~y^2} \right]dy}}$

• This is a standard integral (see section 23.19). We have:

$\small{F~=~(-1)\int{\left[\sqrt{a^2~-~y^2} \right]dy}~=~(-1)\left[\frac{x}{2} \sqrt{a^2~-~y^2}~+~\frac{a^2}{2} \sin^{-1}\frac{y}{a} \right]}$
Therefore, $\small{A~=~(-1)\left[\frac{y}{2} \sqrt{a^2~-~y^2}~+~\frac{a^2}{2} \sin^{-1}\frac{y}{a} \right]_0^{a}}$

$\small{~=~(-1)\left[\frac{a}{2} \sqrt{a^2~-~a^2}~+~\frac{a^2}{2} \sin^{-1}\frac{a}{a} \right]~-~(-1)\left[\frac{0}{2} \sqrt{a^2~-~0^2}~+~\frac{a^2}{2} \sin^{-1}\frac{0}{a} \right]}$

$\small{~=~(-1)\left[0~+~\frac{a^2}{2} \sin^{-1}1 \right]~+~\left[0~+~\frac{a^2}{2} \sin^{-1}0 \right]}$

$\small{~=~(-1)\left[\frac{a^2}{2} \left(\frac{\pi}{2} \right) \right]~+~\left[0~+~0 \right]~=~-\frac{\pi a^2}{4}}$

• Area cannot be −ve. We must take the absolute value. So we get:

$\small{A~=~ \left|-\frac{\pi a^2}{4} \right|~=~\frac{\pi a^2}{4}}$

4. Since the circle is symmetrical about both x and y axes, total area of the circle is four times the area of OBCOB.

• We can write:
Whole area enclosed by the circle
$\small{~=~(4)\frac{\pi \,a^2}{4}~=~\pi\,a^2}$

• We get the same result in both methods. For this problem, there is a total of eight methods (vertical or horizontal strip in each of the four quadrants) available. The reader may try all the eight methods to get a good understanding about the process.

Solved example 24.2
Find the area enclosed by the ellipse $\small{\frac{x^2}{a^2}~+~ \frac{y^2}{b^2}~=~1}$
Solution:
1. First we write the given equation in the form: y = f(x)
$\small{\frac{x^2}{a^2}~+~ \frac{y^2}{b^2}~=~1}$

$\small{\Rightarrow \frac{y^2}{b^2}~=~1~-~\frac{x^2}{a^2}}$

$\small{\Rightarrow y^2~=~b^2 \left(1~-~\frac{x^2}{a^2} \right)~=~b^2 \left(\frac{a^2~-~x^2}{a^2} \right)~=~\frac{b^2}{a^2}\left(a^2~-~x^2 \right)}$

$\small{\Rightarrow y~=~f(x)~=~\pm \frac{b}{a} \sqrt{a^2~-~x^2}}$

• In the above equation, if we input all x values from the interval [−a,a], we will get the ordered pairs, which when plotted, will give the red ellipse in fig.24.6 below:

Fig.24.6

2. Consider fig.24.6(a) above. We want the area of the portion shaded in violet color. This portion is named as OABOA.

• The portion shaded in violet color is bounded by four items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = 0 (y-axis)
    ♦ The vertical line x = a
    ♦ The horizontal line y=0 (x-axis)

• Consider the thin vertical strip of width dx. This strip is situated at a distance of x from O. So height of the strip will be f(x). So area of the strip will be f(x) dx.

Therefore, area (A) of the violet portion can be obtained as:
$\small{A~=~\int_0^a{\left[f(x) \right]dx}~=~\int_0^a{\left[\frac{b}{a} \sqrt{a^2~-~x^2} \right]dx}}$

• Here we discard $\small{f(x)~=~-\frac{b}{a} \sqrt{a^2~-~x^2}}$  and take $\small{f(x)~=~+\frac{b}{a} \sqrt{a^2~-~x^2}}$. This is because, OABOA is in the first quadrant. In this quadrant, all y values are +ve.

3. This integration can be done as shown below:

• First we find the indefinite integral F:

$\small{F~=~\frac{b}{a} \int{\left[\sqrt{a^2~-~x^2} \right]dx}}$

• This is a standard integral (see section 23.19). We have:

$\small{F~=~\int{\left[\sqrt{a^2~-~x^2} \right]dx}~=~\frac{x}{2} \sqrt{a^2~-~x^2}~+~\frac{a^2}{2} \sin^{-1}\frac{x}{a}}$
Therefore, $\small{A~=~\left[\frac{x}{2} \sqrt{a^2~-~x^2}~+~\frac{a^2}{2} \sin^{-1}\frac{x}{a} \right]_0^{a}}$

$\small{~=~\frac{b}{a} \left[\frac{a}{2} \sqrt{a^2~-~a^2}~+~\frac{a^2}{2} \sin^{-1}\frac{a}{a} \right]~-~\frac{b}{a} \left[\frac{0}{2} \sqrt{a^2~-~0^2}~+~\frac{a^2}{2} \sin^{-1}\frac{0}{a} \right]}$

$\small{~=~\frac{b}{a} \left[0~+~\frac{a^2}{2} \sin^{-1}1 \right]~-~\frac{b}{a} \left[0~+~\frac{a^2}{2} \sin^{-1}0 \right]}$

$\small{~=~\frac{b}{a} \left[\frac{a^2}{2} \left(\frac{\pi}{2} \right) \right]~-~\frac{b}{a} \left[0~+~0 \right]~=~\frac{\pi ab}{4}}$

4. In the fig.24.6(a) above, we see that, the ellipse is symmetrical about both x and y axes. So the total area of the ellipse is four times the area of OABOA.

• We can write:
Whole area enclosed by the ellipse
$\small{~=~(4)\frac{\pi \,ab}{4}~=~\pi\,ab}$

Alternate method:

1. First we write the given equation in the form: x = f(y)
$\small{\frac{x^2}{a^2}~+~ \frac{y^2}{b^2}~=~1}$

$\small{\Rightarrow \frac{x^2}{a^2}~=~1~-~\frac{y^2}{b^2}}$

$\small{\Rightarrow x^2~=~a^2 \left(1~-~\frac{y^2}{b^2} \right)~=~a^2 \left(\frac{b^2~-~y^2}{b^2} \right)~=~\frac{a^2}{b^2}\left(b^2~-~y^2 \right)}$

$\small{\Rightarrow x~=~f(y)~=~\pm \frac{a}{b} \sqrt{b^2~-~y^2}}$

• In the above equation, if we input all y values from the interval [−b,b], we will get the ordered pairs, which when plotted, will give the red ellipse in fig.24.6 above.

2. Consider fig.24.6(a) above. We want the area of the portion shaded in blue color. This portion is named as OA'B'OA'.

• The portion shaded in blue color is bounded by four items:
    ♦ The curve y = f(x)
    ♦ The horizontal line y = 0 (x-axis)
    ♦ The horizontal line y = −b
    ♦ The vertical line x = 0 (y-axis)

• Consider the thin horizontal strip of thickness dy. This strip is situated at a distance of y from O. So length of the strip will be f(y). So area of the strip will be f(y) dy.

Therefore, area (A) of the blue portion can be obtained as:
$\small{A~=~\int_{-b}^0{\left[f(y) \right]dy}~=~\int_{-b}^0{\left[-\frac{a}{b} \sqrt{b^2~-~y^2} \right]dy}}$

• Here we discard $\small{f(y)~=~+\frac{a}{b} \sqrt{b^2~-~y^2}}$  and take $\small{f(y)~=~-\frac{a}{b} \sqrt{b^2~-~y^2}}$. This is because, OA'B'OA' is in the third quadrant. In this quadrant, all x values are −ve.

3. This integration can be done as shown below:

• First we find the indefinite integral F:

$\small{F~=~-\frac{a}{b} \int{\left[\sqrt{b^2~-~y^2} \right]dy}}$

• This is a standard integral (see section 23.19). We have:

$\small{F~=~\int{\left[\sqrt{b^2~-~y^2} \right]dy}~=~\frac{y}{2} \sqrt{b^2~-~y^2}~+~\frac{b^2}{2} \sin^{-1}\frac{y}{b}}$
Therefore, $\small{A~=~\left[\frac{y}{2} \sqrt{b^2~-~y^2}~+~\frac{b^2}{2} \sin^{-1}\frac{y}{b} \right]_{-b}^{0}}$

$\small{~=~\left(-\frac{a}{b} \right) \left[\frac{0}{2} \sqrt{b^2~-~0^2}~+~\frac{b^2}{2} \sin^{-1}\frac{0}{b} \right]~-~\left(-\frac{a}{b} \right) \left[\frac{-b}{2} \sqrt{b^2~-~(-b)^2}~+~\frac{b^2}{2} \sin^{-1}\frac{-b}{b} \right]}$

$\small{~=~\left(-\frac{a}{b} \right) \left[0~+0 \right]~+~\left(\frac{a}{b} \right) \left[0~+~\frac{b^2}{2} \sin^{-1}(-1) \right]~~\because \sin^{-1}(-1)~=~-\sin^{-1}(1) }$

$\small{~=~0~+~\left(\frac{a}{b} \right) \left[-\frac{b^2}{2} \sin^{-1}(1) \right]}$

$\small{~=~\frac{a}{b} \left[-\frac{b^2}{2} \left(\frac{\pi}{2} \right) \right]~=~\frac{-\pi ab}{4}}$

• Area cannot be −ve. We must take the absolute value. So we get:

$\small{A~=~ \left|-\frac{\pi ab}{4} \right|~=~\frac{\pi ab}{4}}$

4. In the fig.24.6(b) above, we see that, the ellipse is symmetrical about both x and y axes. So the total area of the ellipse is four times the area of OA'B'OA'.

• We can write:
Whole area enclosed by the ellipse
$\small{~=~(4)\frac{\pi \,ab}{4}~=~\pi\,ab}$

• We get the same result in both methods. For this problem, there is a total of eight methods (vertical or horizontal strip in each of the four quadrants) available. The reader may try all the eight methods to get a good understanding about the process.


In the next section, we will see area bounded by a curve and a line.

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