24. The area bounded by the curve y = sin x and the x-axis between x = 0 and x = 3π/2 is ______ sq. units (answer in integer). 

24. The area bounded by the curve y = sin x and the x-axis between x = 0 and x = 3π/2 is ______ sq. units (answer in integer).

Area Bounded by y = sin x and the x-Axis Between x = 0 and x = 3π/2

Understanding the Given Area Under the Curve Problem

This question asks us to calculate the total geometrical area enclosed between the curve y = sin x and the x-axis over the interval from x = 0 to x = 3π/2. The problem is based on definite integration, but an important feature of the sine curve must be considered before writing the integral.

The curve y = sin x does not remain above the x-axis throughout the given interval. From x = 0 to x = π, the value of sin x is positive, so the curve lies above the x-axis. However, from x = π to x = 3π/2, the value of sin x is negative, so the curve lies below the x-axis.

Since the question asks for the area bounded by the curve and the x-axis, both regions must contribute positively to the final answer. Therefore, the interval must be divided at x = π, where the sine curve crosses the x-axis.

Behavior of the Curve y = sin x on the Given Interval

The standard sine curve begins at the origin because:

sin 0 = 0

It rises above the x-axis and reaches its maximum value at x = π/2:

sin(π/2) = 1

The curve then returns to the x-axis at x = π:

sin π = 0

After x = π, the sine function becomes negative. At x = 3π/2, it reaches:

sin(3π/2) = −1

Therefore, the interval from 0 to 3π/2 contains one complete positive region and one negative region. For calculating geometrical area, the magnitude of both regions must be added.

Formula for the Area Between a Curve and the x-Axis

If a function f(x) remains above the x-axis on an interval [a, b], the area is:

Area = ∫ab f(x) dx

If the function lies below the x-axis, the definite integral becomes negative. However, geometrical area cannot be negative. Therefore, the magnitude of the integral must be taken.

In general:

Total area = ∫ |f(x)| dx

For the present problem, the sine function changes sign at x = π. Therefore, the total area is calculated by dividing the interval into two parts:

Total area = Area from 0 to π + Area from π to 3π/2

Step-by-Step Solution

Step 1: Identify Where the Curve Crosses the x-Axis

The curve crosses the x-axis wherever:

sin x = 0

Within the given interval 0 ≤ x ≤ 3π/2, the relevant zero points are:

x = 0 and x = π

The point x = π is especially important because the sign of sin x changes there. Therefore, the total area must be calculated separately over the intervals:

0 ≤ x ≤ π

and:

π ≤ x ≤ 3π/2

Step 2: Calculate the Area from x = 0 to x = π

Between 0 and π, the sine curve lies above the x-axis. Therefore, the first area is:

A1 = ∫0π sin x dx

The antiderivative of sin x is:

∫ sin x dx = −cos x

Therefore:

A1 = [−cos x]0π

Applying the limits:

A1 = −cos π − (−cos 0)

Using:

cos π = −1

and:

cos 0 = 1

we obtain:

A1 = −(−1) + 1

Therefore:

A1 = 2 square units

Step 3: Calculate the Area from x = π to x = 3π/2

Between π and 3π/2, the sine curve lies below the x-axis. Therefore, the definite integral of sin x over this interval will be negative.

The signed integral is:

π3π/2 sin x dx

Using the antiderivative −cos x:

= [−cos x]π3π/2

Applying the limits:

= −cos(3π/2) − (−cos π)

Since:

cos(3π/2) = 0

and:

cos π = −1

we get:

= 0 − 1

Therefore, the signed integral is:

−1

However, the question asks for geometrical area, which must be positive. Hence:

A2 = |−1|

Therefore:

A2 = 1 square unit

Step 4: Add the Areas of Both Regions

The total area bounded by the curve and the x-axis is the sum of the two positive geometrical areas:

Total area = A1 + A2

Substituting the calculated values:

Total area = 2 + 1

Therefore:

Total area = 3 square units

Why the Direct Integral from 0 to 3π/2 Does Not Give the Required Area

If we directly evaluate the definite integral over the complete interval, we obtain:

03π/2 sin x dx

Using the antiderivative −cos x:

= [−cos x]03π/2

Therefore:

= −cos(3π/2) + cos 0

= 0 + 1

= 1

This value represents the net signed area, not the total geometrical area. The positive region contributes +2, while the region below the x-axis contributes −1. Therefore, the direct integral gives:

2 − 1 = 1

However, the question asks for the area bounded by the curve and the x-axis. Geometrical area is always positive, so the correct calculation is:

2 + 1 = 3

Alternative Solution Using the Absolute Value of sin x

The total geometrical area can also be written as:

Area = ∫03π/2 |sin x| dx

Since sin x is positive between 0 and π and negative between π and 3π/2:

|sin x| = sin x, for 0 ≤ x ≤ π

and:

|sin x| = −sin x, for π ≤ x ≤ 3π/2

Therefore:

Area = ∫0π sin x dx − ∫π3π/2 sin x dx

Substituting the values of the two integrals:

Area = 2 − (−1)

Hence:

Area = 3 square units

Geometrical Interpretation of the Result

The sine curve forms a complete positive arch between x = 0 and x = π. The area of this region is 2 square units. From x = π to x = 3π/2, the curve forms half of a negative arch below the x-axis, whose geometrical area is 1 square unit.

Since both regions are enclosed between the curve and the x-axis, both must be counted positively. Therefore, the complete bounded area is the sum of 2 square units and 1 square unit.

This distinction between signed integral and total geometrical area is essential whenever a curve crosses the x-axis within the interval of integration.

Final Answer

The area bounded by y = sin x and the x-axis between x = 0 and x = 3π/2 is 3 square units.

Answer: 3

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