24.5 - Miscellaneous Examples (2) on Application of Integrals

In the previous section, we saw some miscellaneous examples. In this section, we will see a few more miscellaneous examples.

Solved example 24.24
Find the area of the region lying in the first quadrant and  bounded by y = 4x², x = 0, y = 1  and y = 4.
Solution:
1. In the fig.24.32 below, the red curve represents
$\small{x=f(y)=\pm \frac{\sqrt y}{2}}$

Fig.24.32

2. We are asked to find the area of the blue region.

• Assuming a thin horizontal strip of width dy, this area is equal to:

$\small{\int_1^4{\left[f(y) \right]dy}~=~\int_1^4{\left[\frac{\sqrt y}{2} \right]dy}~=~\frac{7}{3}}$ sq.units

[Here we use $\small{\frac{\sqrt y}{2}}$

Instead of $\small{-\frac{\sqrt y}{2}}$

This is because, in the first quadrant, x values are +ve]

(The reader may write all steps related to the integration process)

Solved example 24.25
Find the area enclosed by the parabola 4y = 3x² and the line 2y = 3x + 12.
Solution:
1. In the fig.24.33 below,

   ♦ the red curve represents
$\small{y=f(x)= \frac{3 x^2}{4}}$

   ♦ the green line represents
$\small{y=f(x)= \frac{3 x}{2}~+~6}$

Fig.24.33

• Solving the two equations, we get the points of intersection:
A(−2,3) and B(4,12)

2. We are asked to find the area of the blue region.

• This area is equal to:

$\small{\int_{-2}^4{\left[f(x)~-~g(x) \right]dx}~=~\int_{-2}^4{\left[\frac{3 x^2}{4}~-~\frac{3 x}{2}~-~6 \right]dx}~=~27}$ sq.units

(The reader may write all steps related to the integration process)

Solved example 24.26
Find the area of the region enclosed by the parabola x² = y, the line y = x + 2 and the x-axis.
Solution:
1. In the fig.24.34 below,

   ♦ the red curve represents
$\small{y=f(x)= x^2}$

   ♦ the green line represents
$\small{y=f(x)= x~+~2}$

Fig.24.34

• Solving the two equations, we get the points of intersection:
A(−1,1) and B(2,4)

2. We are asked to find the area of the blue region.

• This area is equal to:

$\small{\int_{-1}^2{\left[f(x)~-~g(x) \right]dx}~=~\int_{-1}^2{\left[x^2~-~x~-~2 \right]dx}~=~\frac{9}{2}}$ sq.units

(The reader may write all steps related to the integration process)

Solved example 24.27
Find the area bounded by the curve y = sin x between x = 0 and x = 2π.
Solution:
1. In the fig.24.35 below, the red curve represents
$\small{y=f(x)= \sin x}$

Fig.24.35

• Solving the equation, y = sin x = 0 we get the points of intersection with the x-axis as: 0, π, 2π, 3π, so on . . .

2. In our present case, the boundaries are x = 0 and x = 2π. So we need to find the sum: (magenta + blue)

3. Area of magenta region
$\small{\int_{0}^\pi{\left[f(x) \right]dx}~=~\int_{0}^\pi{\left[\sin x \right]dx}~=~2}$ sq.units

(The reader may write all steps related to the integration process)

4. Area of blue region
$\small{\int_{\pi}^{2\pi}{\left[f(x) \right]dx}~=~\int_{\pi}^{2\pi}{\left[\sin x \right]dx}~=~-2}$

(The reader may write all steps related to the integration process)

• Area cannot be −ve. So we take the absolute value. We can write:
Area of blue region = |−2| = 2 sq.units

5. Based on steps (3) and (4), we get the required area as:
(2 + 2) = 4 sq.units

Solved example 24.28
Find the area enclosed between the parabola y² = 4ax and the line y = mx
Solution:
1. In the fig.24.36 below,
    ♦ Red curve represents $\small{y~=~f(x)~=~\pm 2 \sqrt{ax}}$
    ♦ Green line represents $\small{y~=~g(x)~=~mx}$

Fig.24.36

• We need only the x-coordinate of the point of intersection. By solving the two equations, we get the x-coordinate as: $\small{\frac{4a}{m^2}}$

2. We are asked to find the area of the blue region. This area is equal to:

$\small{\int_0^{\frac{4a}{m^2}}{\left[f(x) - g(x) \right]dx}~=~\int_0^{\frac{4a}{m^2}}{\left[2 \sqrt{ax}~-~mx \right]dx}}$

[Here we use $\small{2 \sqrt{ax}}$

Instead of $\small{-2 \sqrt{ax}}$

This is because, in the first quadrant, y values are +ve]

$\small{~=~2 \sqrt{a} \left[\frac{x^{3/2}}{3/2} \right]_0^{\frac{4a}{m^2}}~-~m \left[\frac{x^{2}}{2} \right]_0^{\frac{4a}{m^2}}}$

$\small{~=~4 \sqrt{a} \left[\frac{x^{3/2}}{3} \right]_0^{\frac{4a}{m^2}}~-~m \left[\frac{x^{2}}{2} \right]_0^{\frac{4a}{m^2}}}$

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

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

$\small{~=~ \left[\frac{32 a^2}{3m^3} \right]~-~ \left[\frac{8 a^2}{ m^3} \right]~=~\frac{8 a^2}{3 m^3}}$ sq.units

Solved example 24.29
Area bounded by the curve y = x³, the x-axis and the ordinates x = −2 and x = 1 is:
(A) −9    (B) −15/4    (C) 15/4    (D) 17/4
Solution:
1. In the fig.24.37 below, the red curve represents
$\small{x=f(y)=x^3}$

Fig.24.37

2. We are asked to find the area of (magenta + blue) region.

3. Area of magenta region
$\small{\int_{-2}^0{\left[f(x) \right]dx}~=~\int_{-2}^0{\left[x^3 \right]dx}~=~-4}$

(The reader may write all steps related to the integration process)

• Area cannot be −ve. So we take the absolute value. We can write:
Area of magenta region = |−4| = 4 sq.units

4. Area of blue region
$\small{\int_{0}^1{\left[f(x) \right]dx}~=~\int_{0}^1{\left[x^3 \right]dx}~=~\frac{1}{4}}$ sq.units

(The reader may write all steps related to the integration process)

5. Based on steps (3) and (4), we can write:

Required area = $\small{4+~\frac{1}{4}~=~\frac{17}{4}}$ sq.units

• So the correct option is (D)

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The link below gives a few more solved examples:

Miscellaneous Exercise

---

In the next chapter, we will see differential equations.

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24.4 - Miscellaneous Examples (1) on Application of Integrals

In the previous section, we completed a discussion on area bounded by a curve and another curve. In this section, we will see some miscellaneous examples.

Solved example 24.17
Find the area of the parabola y² = 4ax bounded by it's latus rectum.
Solution:
1. We know that:
    ♦ y² = 4ax is a parabola with the vertex at the origin.
    ♦ The latus rectum has the equation x = a.

2. First we write the equation of the parabola in the form y = f(x). We get:
$\small{y~=~f(x)~=~\pm 2 \sqrt{ax}}$

• This is the red parabola in fig.24.23 below:

Fig.24.23

• Since the parabola is symmetrical about the x-axis, twice the blue area will give us the required result.  

3. So our next task is to find the blue area. This area is bounded by three items:
    ♦ The curve y = f(x)
    ♦ The vertical line x = a
    ♦ The horizontal line y = 0 (x-axis)
• So the interval is: [0,a]

• Therefore we can write:
Blue area = $\small{\int_0^a{\left[f(x) \right]dx}~=~\int_0^a{\left[2 \sqrt{ax} \right]dx}~=~2 \sqrt{a} \int_0^a{\left[\sqrt{x} \right]dx}}$

[Here we use $\small{2 \sqrt{ax}}$

Instead of $\small{-2 \sqrt{ax}}$

This is because, in the first quadrant, y values are +ve]

$\small{~=~2 \sqrt{a} \left[\frac{x^{3/2}}{3/2} \right]_0^a~=~4 \sqrt{a} \left[\frac{x^{3/2}}{3} \right]_0^a~=~4 \sqrt{a} \left[\frac{a^{3/2}}{3} \right]}$

$\small{~=~4 \sqrt{a} \left[\frac{a \sqrt a}{3} \right]~=~\frac{4 a^2}{3}}$ sq.units

4. Twice the blue area = $\small{\frac{8 a^2}{3}}$ sq.units

Solved example 24.18
Prove that the curves y² = 4x and x² = 4y divide the area of the square bounded by x = 0, x = 4, y = 4 and y = 0 into three equal parts.
Solution:
1. First we represent the given curves as functions:

$\small{y~=~f(x)~=~\pm 2 \sqrt x~~~~\rm{and}~~~~y~=~g(x)~=~\frac{x^2}{4}}$

• Solving the two equations, we see that, they intersect at (0,0), (4,4) and (4,−4).

• We are interested in (0,0) and (4,4) because, they are in the I quadrant. They are marked as O and A in the fig.24.24 below:

Fig.24.24

• The horizontal line can be represented as: y = h(x) = 4

2. The blue area can be obtained as:

$\small{\int_0^4{\left[h(x) - f(x) \right]dx}~=~\int_0^4{\left[4 - 2 \sqrt x \right]dx}~=~\frac{16}{3}}$ sq.units

(The reader may write all steps related to the integration process)

3. The magenta  area can be obtained as:

$\small{\int_0^4{\left[f(x) - g(x) \right]dx}~=~\int_0^4{\left[2 \sqrt x - \frac{x^2}{4} \right]dx}~=~\frac{16}{3}}$ sq.units

(The reader may write all steps related to the integration process)

4. The violet area can be obtained as:

$\small{\int_0^4{\left[g(x) \right]dx}~=~\int_0^4{\left[\frac{x^2}{4} \right]dx}~=~\frac{16}{3}}$ sq.units

(The reader may write all steps related to the integration process)

5. One third of the area of the square ABOC

$\small{~=~\frac{1}{3} (4 \times 4)~=~\frac{16}{3}}$ sq.units

6. From steps (2), (3), (4) and (5), we see that:

Area of blue = Area of magenta = Area of violet

= one third of the area of the square.

• That means, the curves divide the square into three equal parts.

Solved example 24.19
Find the area of the region
$\small{\{(x,y):0 \le y\le x^2 + 1,~~0 \le y\le x + 1,~~0 \le x \le 2 \}}$
Solution:
• In this problem, a region is given as a set.
   ♦ That set contains three inequalities.
   ♦ Any ordered pair (x,y) which satisfies all the three inequalities, is eligible to be a member of the set.
   ♦ For any inequality, there will be a corresponding region on the x-y plane. That is., any point (x,y) in that region will satisfy that inequality.
   ♦ In our present case, there will be three regions. The points in the intersection of the three regions, will satisfy all three inequalities.
   ♦ We are asked to find the area of that intersection region.

1. In the fig.24.25 below, the red curve represents $\small{y~=~f(x)~=~x^2 + 1}$

Fig.24.25

• The inequality: $\small{0 \le y\le x^2 + 1}$ will be represented by a region. This region is hatched with vertical lines. That means, if any region has vertical lines, that region will be part of the inequality.

• Note that all the region below the red curve has vertical lines.

• However, the vertical lines do not extend below the x-axis. This is because, it is specified that 0 ≤ y

2. In the fig.24.25 above, the green line represents $\small{y~=~g(x)~=~x + 1}$

• The inequality: $\small{0 \le y\le x + 1}$ will be represented by a region. This region is hatched with slanting lines. That means, if any region has slanting lines, that region will be part of the inequality.

• Note that all the region below the green line has slanting lines.

• However, the slanting lines do not extend below the x-axis. This is because, it is specified that 0 ≤ y

3. In the fig.24.25 above, the magenta line represents $\small{x~=~2}$

• The inequality: $\small{0 \le x\le 2}$ will be represented by a region. This region is hatched with horizontal lines. That means, if any region has horizontal lines, that region will be part of the inequality.

• Note that all the region to the left of the magenta line has horizontal lines.

• However, the horizontal lines do not extend to the left of the y-axis. This is because, it is specified that 0 ≤ x

4. We see that, a region has all the three type:
Vertical, slanting and horizontal lines.

• This region is the intersection of all the three regions that we saw above. Such a region will satisfy all three inequalities. We are asked to find the area of that region.

• This region of intersection is shown in fig.24.26 below:

Fig.24.26

• Coordinates of A, B and C can be obtained by solving appropriate pairs of equations

5. Area of pink region

$\small{~=~\int_0^1{\left[f(x) \right]dx}~=~\int_0^1{\left[x^2 + 1 \right]dx}~=~\frac{4}{3}}$ sq.units

(The reader may write all steps related to the integration process)

6. Area of blue region

$\small{~=~\int_1^2{\left[g(x) \right]dx}~=~\int_1^2{\left[x + 1 \right]dx}~=~\frac{5}{2}}$ sq.units

(The reader may write all steps related to the integration process)

7. So we get:
Pink + Blue = $\small{\frac{4}{3}~+~\frac{5}{2}~=~\frac{23}{6}}$ sq.units

Solved example 24.20
Find the area of the region
$\small{\{(x,y): y^2 \le 4x,~~4x^2 + 4y^2 \le 9 \}}$
Solution:
• In this problem, a region is given as a set.
   ♦ That set contains two inequalities.
   ♦ Any ordered pair (x,y) which satisfies both the inequalities, is eligible to be a member of the set.
   ♦ For any inequality, there will be a corresponding region on the x-y plane. That is., any point (x,y) in that region will satisfy that inequality.
   ♦ In our present case, there will be two regions. The points in the intersection of the two regions, will satisfy both the inequalities.
   ♦ We are asked to find the area of that intersection region.

1. In the fig.24.27 below, the red curve represents $\small{y~=~f(x)~=~\pm 2 \sqrt x}$

Fig.24.27

• The inequality: $\small{y^2 \le 4x}$ will be represented by a region. This region is hatched with vertical lines. That means, if any region has vertical lines, that region will be part of the inequality.

• Note that all the region inside the red curve has vertical lines.

2. In the fig.24.27 above, the green curve represents $\small{y~=~g(x)~=~\pm \sqrt{\frac{9}{4}~-~x^2}}$

• The inequality: $\small{4x^2 + 4y^2 \le 9}$ will be represented by a region. This region is hatched with horizontal  lines. That means, if any region has horizontal lines, that region will be part of the inequality.

• Note that all the region inside the green circle has horizontal lines.

3. We see that, a particular region has both the types:
Vertical and horizontal lines.

• This region is the intersection of all the two regions that we saw above. Such a region will satisfy both the inequalities. We are asked to find the area of that region.

• This region of intersection is shown in fig.24.28 below:

Fig.24.28

• Coordinates of A and B can be obtained by solving the two equations

4. Area of blue region

$\small{~=~\int_0^{0.5}{\left[g(x) - f(x) \right]dx}~=~\int_0^{0.5}{\left[\sqrt{\frac{9}{4}~-~x^2}~-~\left(2 \sqrt x \right) \right]dx}}$ sq.units

$\small{~=~\left[\frac{27}{24} \sin^{-1}\left(\frac{1}{3} \right)~-~\frac{\sqrt 2}{12} \right]}$ sq.units

(The reader may write all steps related to the integration process)

[Here we use $\small{\sqrt{\frac{9}{4}~-~x^2}}$

Instead of $\small{-\sqrt{\frac{9}{4}~-~x^2}}$

This is because, in the first quadrant, y values are +ve]

6. Blue + Magenta gives one fourth the total area of the circle.
• So area of magenta region

$\small{~=~\Bigg[\frac{\pi (3/2)^2}{4}~-~\left[\frac{27}{24} \sin^{-1}\left(\frac{1}{3} \right)~-~\frac{\sqrt 2}{12} \right]\Bigg]}$ sq.units

$\small{~=~\Bigg[\frac{9 \pi }{16}~-~\frac{27}{24} \sin^{-1}\left(\frac{1}{3} \right)~+~\frac{\sqrt 2}{12} \Bigg]}$ sq.units

7. The area of intersection, is twice the magenta area. So we can write:

Required area $\small{~=~\Bigg[\frac{9 \pi }{8}~-~\frac{27}{12} \sin^{-1}\left(\frac{1}{3} \right)~+~\frac{\sqrt 2}{6} \Bigg]}$ sq.units

$\small{~=~\Bigg[\frac{9 \pi }{8}~-~\frac{9}{4} \sin^{-1}\left(\frac{1}{3} \right)~+~\frac{1}{3 \sqrt 2} \Bigg]}$ sq.units

Solved example 24.21
Find the area bounded by the curves
$\small{\{(x,y): y \ge x^2,~~\rm{and}~~y~=~|x| \}}$
Solution:
• In this problem, the set contains an inequality.
   ♦ For any inequality, there will be a corresponding region on the x-y plane. That is., any point (x,y) in that region will satisfy that inequality.
   ♦ The above mentioned region should be bounded by the line $\small{y~=~|x|}$.
   ♦ Any point (x,y), in that bounded region is eligible to be a member of the set.
   ♦ We are asked to find the area of that bounded region.

1. In the fig.24.29 below, the red curve represents $\small{y~=~f(x)~=~x^2}$. It is a parabola.

Fig.24.29

The interior of the parabola is hatched with vertical lines. Any point (x,y) in the interior will satisfy the inequality $\small{y \ge x^2}$. It is an infinite region.

2. The above mentioned infinite region is bounded by the green line and pink line.
   ♦ The green line represent $\small{y~=~g(x)~=~x}$
   ♦ The pink line represent $\small{y~=~h(x)~=~-x}$
   ♦ The two lines together represent $\small{y~=~|x|}$

• The bounded region is hatched with both vertical and horizontal lines. We want the area of this hatched region.

3. The equations of the curves can be solved to find the points of intersection.
   ♦ Solving red and green, we get: A(1,1)
   ♦ Solving red and pink, we get: B(−1,1)

4. The area AOA

$\small{~=~\int_0^{1}{\left[g(x) - f(x) \right]dx}~=~\int_0^{1}{\left[x~-~x^2 \right]dx}~=~\frac{1}{6}}$ sq.units

(The reader may write all steps related to the integration process)

5. Since the graph is symmetrical, we can write:

Required area = $\small{2\left(\frac{1}{6} \right)~=~\frac{1}{3}}$ sq.units

Solved example 24.22
Using the method of integration find the area bounded by the curve $\small{|x| + |y| = 1}$
[Hint: The required region is bounded by lines $\small{x+y=1,~x-y=1,~-x+y=1,~\rm{and}~-x-y=1}$]
Solution:
1. Consider the equation $\small{|x| + |y| = 1}$
• For this equation, four cases are possible:
(i) x is +ve and y is also +ve
Then |x| is x. |y| is y
The equation becomes $\small{x+y=1}$

(ii) x is +ve and y is −ve
Then |x| is x. |y| is −y
The equation becomes $\small{x-y=1}$

(iii) x is −ve and y is +ve
Then |x| is −x. |y| is y
The equation becomes $\small{-x+y=1}$

(iv) x is −ve and y is also −ve
Then |x| is −x. |y| is −y
The equation becomes $\small{-x-y=1}$

2. Now we can plot the graphs:
• Case (i) gives:
$\small{y = f(x) = 1-x}$
This is the red line in fig.24.30 below:

Fig.24.30

• Case (ii) gives:
$\small{y = g(x) = x-1}$
This is the green line in fig.24.30 above.

• Case (iii) gives:
$\small{y = h(x) = 1+x}$
This is the pink line in fig.24.30 above.

• Case (iv) gives:
$\small{y = j(x) = -x-1}$
This is the blue line in fig.24.30 above.

3. We are asked to find the area of ABCD
• This area is the sum of the areas of OAB, OBC, OCD and ODA
• OAB is shaded with magenta color. It's area

$\small{~=~\int_0^{1}{\left[f(x) \right]dx}~=~\int_0^{1}{\left[1-x \right]dx}~=~\frac{1}{2}}$ sq.units

4. Due to symmetry, all four areas are equal.
Therefore, total area of ABCD = $\small{4\left(\frac{1}{2} \right)~=~2}$ sq.units

Solved example 24.23
Sketch the graph of y = |x+3| and evaluate $\small{\int_{-6}^{0}{\left[\left|x+3  \right| \right]dx}}$
Solution:
1. Consider the equation $\small{y~=~\left|x+3  \right|}$ 
• For this equation, two cases are possible:
(i) x is less than −3
Then (x+3) is −ve. So |x+3| is −(x+3)
The equation becomes $\small{y=-x-3}$

(ii) x is greater than −3
Then (x+3) is +ve. So |x+3| is +(x+3)
The equation becomes $\small{y=x+3}$

2. Now we can plot the graphs:
• Case (i) gives:
$\small{y = f(x) = -x-3}$
This is the red line in fig.24.31 below:

Fig.24.31

• Case (ii) gives:
$\small{y = g(x) = x+3}$
This is the green line in fig.24.31 above.

The two lines together represent y = |x+3|

3. We are asked to find the area of magenta + blue
• Magenta area

$\small{~=~\int_{-6}^{-3}{\left[f(x) \right]dx}~=~\int_{-6}^{-3}{\left[-x-3 \right]dx}~=~\frac{9}{2}}$ sq.units

• Blue area

$\small{~=~\int_{-3}^{0}{\left[f(x) \right]dx}~=~\int_{-3}^{0}{\left[x+3 \right]dx}~=~\frac{9}{2}}$ sq.units

4. Therefore, the required area = $\small{2\left(\frac{9}{2} \right)~=~9}$ sq.units.

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In the next section, we will see a few more miscellaneous examples.

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24.3 - Area Between Two Curves

In the previous section, we completed a discussion on area bounded by a curve and a line. In this section, we will see area bounded by a curve and another curve.

The basic details can be written in 2 steps:
1. In fig.24.16 below,
   ♦ The red curve represent y = f(x)
   ♦ The green curve represent y = g(x)

Fig.24.16

• The curves intersect at two points:
   ♦ At the first point, x-coordinate is 'a'
   ♦ At the second point, x-coordinate is 'b'
(We do not want their y-coordinates)

2. We want to find the area bounded by the two curves. In the fig., it is shaded in blue color.
• Consider the thin yellow strip of width dx. This strip is at a distance of x from O.
   ♦ So the y-coordinate of the bottom end of this strip will be g(x).
   ♦ Also, the y-coordinate of the top end of this strip will be f(x).
• So height of this strip will be $\small{[f(x)~-~g(x)]}$
• So area of this strip will be $\small{[f(x)~-~g(x)]dx}$
• Therefore, area A of the blue region can be obtained as:
$\small{A~=~\int_a^b{\left[f(x)~-~g(x) \right]dx}}$ 

Note:
In the interval [a,b], f(x) ≥ g(x)  
So in the blue region, wherever we place the yellow strip, it's height will be always $\small{[f(x)~-~g(x)]}$

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Alternate method:

This can be written in 3 steps:

1. In the fig.24.16 above, consider the area bounded by 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 will call this area as A₁. We can write:
$\small{A_1~=~\int_a^b{\left[f(x) \right]dx}}$   

2. In the same fig.24.16 above, consider the area bounded by four items:
    ♦ The curve y = g(x)
    ♦ The vertical line x = a
    ♦ The vertical line x = b
    ♦ The horizontal line y = 0 (x-axis)
• We will call this area as A₂. We can write:
$\small{A_2~=~\int_a^b{\left[g(x) \right]dx}}$

3. From the fig.24.16, we have:
A₂ + Blue area = A₁
• So we get:
Blue area = A₁ − A₂
$\small{~=~\int_a^b{\left[f(x) \right]dx}~-~\int_a^b{\left[g(x) \right]dx}}$
$\small{~=~\int_a^b{\left[f(x)~-~g(x) \right]dx}}$      

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Let us see another case. It can be explained in 2 steps:

1. In fig.24.17 below,
   ♦ The red curve represent y = f(x)
   ♦ The green curve represent y = g(x)

Fig.24.17

• The curves intersect at three points:
   ♦ At the first point, x-coordinate is 'a'
   ♦ At the second point, x-coordinate is 'c'
   ♦ At the third point, x-coordinate is 'b'
(We do not want their y-coordinates)

2. We want to find the area bounded by the two curves. That is., we want (A₁ + A₂) in the fig.

• A₁ can be calculated just as we did in the previous fig.24.16.
We get: $\small{A_1~=~\int_a^c{\left[f(x)~-~g(x) \right]dx}}$
• Let us find A₂:
Consider the thin yellow strip of width dx. This strip is at a distance of x from O.
   ♦ So the y-coordinate of the bottom end of this strip will be f(x).
   ♦ Also, the y-coordinate of the top end of this strip will be g(x).
• So height of this strip will be $\small{[g(x)~-~f(x)]}$
• So area of this strip will be $\small{[g(x)~-~f(x)]dx}$
• Therefore, area A₂ of the violet region can be obtained as:
$\small{A_2~=~\int_c^b{\left[f(x)~-~g(x) \right]dx}}$ 

Note:
In the interval [c,b], g(x) ≥ f(x)  
So in the violet region, wherever we place the yellow strip, it's height will be always $\small{[g(x)~-~f(x)]}$

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Solved example 24.12
Find the area of the region bounded by the two parabolas y = x² and y² = x.
Solution:
1. First we write the given equations in the form: y = f(x) and y = g(x)
$\small{y~=~f(x)~=~x^2}$

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

2. Solving the two equations, we find that, they intersect at (0,0) and (1,1).
The point (1,1) is marked as point A in fig.24.18 below:

Fig.24.18

The region bounded by the two curves is shaded in blue color. So we are interested in the interval [0,1]

3. From the fig., it is clear that $\small{g(x)~\ge~f(x)}$ in the interval [0,1].

4. So, if we assume a thin vertical strip of width dx in the magenta region, then the height of that strip will be $\small{[g(x)~-~f(x)]}$
So area of the strip will be $\small{[g(x)~-~f(x)]dx}$

5. Therefore, area A of the blue region can be obtained as:

$\small{A~=~\int_0^1{\left[g(x)~-~f(x) \right]dx}~=~\int_0^1{\left[\sqrt x~-~x^2 \right]dx}~=~\frac{1}{3}}$ sq.units

(The reader may write all steps related to the integration process)

Solved example 24.13
Find the area lying above the x-axis and included between the circle x² + y² = 8x and inside of the parabola y² = 4x.
Solution:
1. Consider the given equation $\small{x^2~+~y^2~=~8x}$

This can be rearranged as:

$\small{x^2~-8x~+~16~-~16~+~y^2~=~0}$

$\small{\Rightarrow (x^2~-8x~+~16)~+~y^2~=~16}$

$\small{\Rightarrow (x-4)^2~+~y^2~=~4^2}$

This is the equation of a circle with center (4,0) and radius 4 units.

2. Next we write the two equations in the form y = f(x) and y = g(x).
For the circle, we can write: $\small{y~=~f(x)~=~\pm \sqrt{4^2~-~(x-4)^2}}$
• In the above equation, if we input all x values from the interval [0,8], we will get the ordered pairs, which when plotted, will give the red circle in fig.24.19 below:

Fig.24.19

For the parabola, we can write: $\small{y~=~g(x)~=~\pm 2 \sqrt{x}}$
• In the above equation, if we input all x values from the interval $\small{[0,\infty]}$, we will get the ordered pairs, which when plotted, will give the green parabola  in fig.24.19 above.

3. Let us solve the equations of the two curves: $\small{x^2~+~y^2~=~8x~\text{and}~y^2~=~4x}$

We get: $\small{x^2~+~4x~=~8x \Rightarrow x^2~-~4x~=~0 }$

$\small{ \Rightarrow x(x-4)~=~0 \Rightarrow x = 0~\text{and}~x=4}$

   ♦ When x = 0, we get: y = 0
   ♦ When x = 4, we get: y = 4
So the two curves intersect at (0,0) and (4,4)

   ♦ (0,0) is the origin O
   ♦ (4,4) is marked as 'A' in the fig.
   
4. We are asked to find the area of OABCO. It is shaded in magenta color.
• We see that,
Area of (OABCO + ODAO) = Area of the semicircle.
(Point D is an arbitrary point, just to define the curved shape between O and A along the circle)
• In other words
magenta + blue = $\small{\frac{\pi r^2}{2}~=~\frac{\pi (4)^2}{2}~=~8 \pi}$ sq.units

5. So our next aim is to find the area of the blue region. This region is bounded by two items:
    ♦ The curve y = f(x)
    ♦ The curve y = g(x)
In the interval [0,4], f(x) ≥ g(x)    
    
Therefore, area of blue region

$\small{~=~\int_0^4{\left[f(x)~-~g(x) \right]dx}~=~\int_0^4{\left[\sqrt{4^2~-~(x-4)^2} ~-~2 \sqrt{x} \right]dx}}$

$\small{~=~\int_0^4{\left[\sqrt{4^2~-~(x-4)^2} \right]dx}~-~\int_0^4{\left[2 \sqrt{x} \right]dx}}$

• Here we use $\small{\sqrt{4^2~-~(x-4)^2} ~\rm{and}~2 \sqrt{x}}$

Instead of $\small{-\sqrt{4^2~-~(x-4)^2} ~\rm{and}~-2 \sqrt{x}}$

This is because, in the first quadrant, y values are +ve.

6. The integration can be done as shown below:

The first term is: $\small{\int_0^4{\left[\sqrt{4^2~-~(x-4)^2} \right]dx}}$

• Here we can use the standard integral:

$\small{ \int{\big[\sqrt{a^2-u^2} \big]dx}~=~\frac{u}{2}\sqrt{a^2 - u^2} ~+~\frac{a^2}{2} \sin^{-1}\frac{u}{a}~+~\rm{C}}$

• In our present case, a = 4 and u = x-4

• So we get:

$\small{\int_0^4{\left[\sqrt{4^2~-~(x-4)^2} \right]dx}}$

$\small{~=~\left[\frac{x-4}{2}\sqrt{4^2 - (x-4)^2} ~+~\frac{4^2}{2} \sin^{-1}\frac{x-4}{4} \right]_0^4}$

$\small{~=~\left[0 ~+~0 \right]~-~\left[(-2)\sqrt{0} ~+~8 \sin^{-1}(-1) \right]}$

$\small{~=~(-1)(8) \left[\sin^{-1}(-1) \right]~=~(8) \left[\sin^{-1}(1) \right]~=~\frac{8 \pi}{2}~=~4 \pi}$ sq.units

7. The second term is:
$\small{\int_0^4{\left[2 \sqrt{x} \right]dx}}$

This gives: $\small{\frac{32}{3}}$ sq.units

8. So from step (5), we get:
Area of blue region = $\small{4 \pi~-~\frac{32}{3}}$ sq.units.

9. So from (4), we get:
Area of magenta region = $\small{8 \pi~-~4 \pi~+~\frac{32}{3}~=~4 \pi~+~\frac{32}{3}}$ sq. units

Solved example 24.14
In the fig.24.20 below, AOBA is the part of the ellipse in the first quadrant such that OA = 2 and OB = 6. Find the area between the arc AB and the chord AB.

Fig.24.20

 
Solution:
1. First we will rearrange the given equation into the form y = f(x)

We have: $\small{\frac{x^2}{4}~+~\frac{y^2}{36}~=~1}$

$\small{\Rightarrow \frac{9 x^2~+~y^2}{36}~=~1 \Rightarrow 9x^2 ~+~y^2~=~36 \Rightarrow y~=~f(x)~=~\pm \sqrt{36~-~9x^2}}$

• 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.24.20 above.

2. We are given the coordinates of end points A and B. So we can easily write the equation of the line AB. We get:

$\small{y-0~=~\left(\frac{6-0}{0-2} \right)(x-2)}$

$\small{\Rightarrow y~=~g(x)~=~-3x + 6}$

3. We are asked to find the area of the blue region in the fig.24.20. This region is bounded by f(x) and g(x). Also in the interval [0,2], f(x) ≥ g(x)

• So the area of the blue region

$\small{~=~\int_0^2{\left[f(x)~-~g(x) \right]dx}~=~\int_0^2{\left[\sqrt{36~-~9x^2} ~-~(-3x + 6) \right]dx}}$

• This integration gives: $\small{(3\pi~-~6)}$ sq.units
(The reader may write all steps related to the integration process)

Solved example 24.15
Using integration find the area of the region bounded by the triangle whose vertices are (1,0), (2,2) and (3,1).
Solution:
1. Let the vertices of the triangle be A(1,0), B(2,2) and C(3,1). They are shown in fig.24.21 below:

Fig.24.21

• We are asked to find the area bounded by the triangle ABC. In the fig above, this required area is separated into two:
   ♦ ABD shaded in magenta color
   ♦ DCB shaded in blue color
• Point D is the intersection of two lines:
   ♦ Perpendicular dropped from B
   ♦ Side AC
• So we want the sum of magenta and blue areas.

2. First we will write the equations of the three lines:
(i) Line AB:

$\small{y-0~=~\left(\frac{2-0}{2-1} \right)(x-1)}$

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

(ii) Line BC:

$\small{y-2~=~\left(\frac{1-2}{3-2} \right)(x-2)}$

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

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

(iii) Line AC:

$\small{y-0~=~\left(\frac{1-0}{3-1} \right)(x-1)}$

$\small{\Rightarrow y~=~\frac{1}{2} (x-1)}$

$\small{\Rightarrow y~=~h(x)~=~\frac{x}{2} - \frac{1}{2}}$

3. Next, we will find the area of magenta region. This area is bounded by three items:

    ♦ The line y = f(x)
    ♦ The line y = h(x)
    ♦ The vertical line x = 2

 Therefore, area of the magenta region

$\small{~=~\int_1^2{\left[f(x)~-~h(x) \right]dx}~=~\int_1^2{\left[2x-2~-~\left(\frac{x}{2} - \frac{1}{2} \right) \right]dx}}$

$\small{~=~\int_1^2{\left[2x-2~-~\frac{x}{2} + \frac{1}{2}  \right]dx}~=~\int_1^2{\left[\frac{3x}{2} - \frac{3}{2}  \right]dx}~=~\frac{3}{4}}$ sq.units

4. Next, we will find the area of blue region. This area is bounded by three items:

    ♦ The line y = g(x)
    ♦ The line y = h(x)
    ♦ The vertical line x = 2

 Therefore, area of the magenta region

$\small{~=~\int_2^3{\left[g(x)~-~h(x) \right]dx}~=~\int_2^3{\left[-x+4~-~\left(\frac{x}{2} - \frac{1}{2} \right) \right]dx}}$

$\small{~=~\int_2^3{\left[-x+4~-~\frac{x}{2} + \frac{1}{2}  \right]dx}~=~\int_2^3{\left[-\frac{3x}{2} + \frac{9}{2}  \right]dx}~=~\frac{3}{4}}$ sq.units

5. Finally, we can calculate the sum:

Magenta area + Blue area = $\small{\frac{3}{4}~+~\frac{3}{4}~=~\frac{3}{2}}$ sq.units

Solved example 24.16
Find the area of the region enclosed between the two circles x² + y² = 4 and (x−2)² + y² = 4.
Solution:
1. Consider the second equation given to us: $\small{(x-2)^2~+~y^2~=~4}$

This is the equation of a circle with center (2,0) and radius 2 units.

2. Next we write the two equations in the form y = f(x) and y = g(x).
For the first circle, we can write:

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

• 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 circle in fig.24.22 below:

Fig.24.22

• For the second circle, we can write:

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

• In the above equation, if we input all x values from the interval [0,4], we will get the ordered pairs, which when plotted, will give the green circle in fig.24.22 above.

3. Let us solve the equations of the two curves: $\small{x^2~+~y^2~=~4~~~\text{and}~~~(x-2)^2~+~y^2~=~4}$

We get: $\small{x = 1 ~~\rm{and}~~y = \pm \sqrt 3 }$

   ♦ (1,√3) is marked as 'A' in the fig.
   
4. We are asked to find the area enclosed between the two circles.
Note that, the two circles are symmetric about the x-axis.
So the magenta region will be half of the required area. Therefore, we need to find the area of the magenta region.

5. Consider the sum: Magenta + Blue
• This sum will be one fourth of the area of the red circle. So we can write:

Magenta + Blue = $\small{\frac{\pi (2)^2}{4}~=~\pi}$ sq.units

6. So our next task is to find the area of the blue region.
This region is bounded by three items:

    ♦ The curve y = f(x)
    ♦ The curve y = g(x)
    ♦ The vertical line x = 1
    ♦ The vertical line x = 0 (y-axis)
• So area of blue region
$\small{~=~\int_0^1{\left[f(x)~-~g(x) \right]dx}~=~\int_0^1{\left[\sqrt{4~-~x^2}~-~\sqrt{2^2~-~(x-2)^2} \right]dx}}$

$\small{~=~\int_0^1{\left[\sqrt{4~-~x^2} \right]dx}~-~\int_0^1{\left[\sqrt{2^2~-~(x-2)^2} \right]dx}}$

• Here we use $\small{\sqrt{4~-~x^2} ~\rm{and}~\sqrt{2^2~-~(x-2)^2}}$

Instead of $\small{-\sqrt{4~-~x^2} ~\rm{and}~-\sqrt{2^2~-~(x-2)^2}}$

This is because, in the first quadrant, y values are +ve.

• This integration gives:
Area of blue region = $\small{(\sqrt 3~-~\frac{\pi}{3})}$ sq.units
(The reader may write all steps related to the integration process)

7. So based on step (5), we get:

Magenta = $\small{\pi~-~\left(\sqrt 3~-~\frac{\pi}{3}\right)~=~\frac{4 \pi}{3}~-~\sqrt 3}$

8. So the required area

$\small{~=~2\left(\frac{4 \pi}{3}~-~\sqrt 3 \right)~=~\left(\frac{8 \pi}{3}~-~2 \sqrt 3 \right)}$ sq.units

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The link below gives a few more solved examples:

Exercise 24.2

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In the next section, we will see some miscellaneous examples.

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