MCQMediumJEE 2024Applications of Integrals (Area)

JEE Mathematics 2024 Question with Solution

The area (in square units) of the region bounded by the parabola y2=4(x2)y^2 = 4(x - 2) and the line y=2x8y = 2x - 8 is:

  • A

    88

  • B

    99

  • C

    66

  • D

    77

Answer

Correct answer:B

Step-by-step solution

Standard Method

Given: The parabola is y2=4(x2)y^2 = 4(x - 2) and the line is y=2x8y = 2x - 8.

Find: The area of the region bounded by these two curves.

Write both curves in terms of xx as a function of yy:

x=y24+2x = \frac{y^2}{4} + 2

and from y=2x8y = 2x - 8,

x=y+82=y2+4x = \frac{y + 8}{2} = \frac{y}{2} + 4

Now find the points of intersection by substituting x=y+82x = \frac{y+8}{2} into the parabola:

y2=4(y+822)y^2 = 4\left(\frac{y + 8}{2} - 2\right) y2=2(y+4)y^2 = 2(y+4) y22y8=0y^2 - 2y - 8 = 0 (y4)(y+2)=0(y-4)(y+2)=0

So, the curves intersect at y=4y = 4 and y=2y = -2.

For y[2,4]y \in [-2,4], the line lies to the right of the parabola, so the required area is

A=24[(y2+4)(y24+2)]dyA = \int_{-2}^{4} \left[\left(\frac{y}{2}+4\right) - \left(\frac{y^2}{4}+2\right)\right] \, dy A=24(y24+y2+2)dyA = \int_{-2}^{4} \left(-\frac{y^2}{4} + \frac{y}{2} + 2\right) \, dy

Integrating,

A=[y312+y24+2y]24A = \left[-\frac{y^3}{12} + \frac{y^2}{4} + 2y\right]_{-2}^{4}

At y=4y=4,

4312+424+2(4)=163+12=203-\frac{4^3}{12} + \frac{4^2}{4} + 2(4) = -\frac{16}{3} + 12 = \frac{20}{3}

At y=2y=-2,

(2)312+(2)24+2(2)=23+14=73-\frac{(-2)^3}{12} + \frac{(-2)^2}{4} + 2(-2) = \frac{2}{3} + 1 - 4 = -\frac{7}{3}

Therefore,

A=203(73)=273=9A = \frac{20}{3} - \left(-\frac{7}{3}\right) = \frac{27}{3} = 9

Hence, the area of the bounded region is 99 square units. The correct option is B.

Intersection First, Then Area

Given: y2=4(x2)y^2 = 4(x - 2) and y=2x8y = 2x - 8.

Find: Area enclosed between the parabola and the line.

Using the line equation,

y=2x8y = 2x - 8 2x=y+82x = y + 8 x=y+82x = \frac{y+8}{2}

Substitute this in the parabola equation:

y2=4(x2)y^2 = 4(x-2) y2=4(y+822)y^2 = 4\left(\frac{y+8}{2} - 2\right) y2=2y+8y^2 = 2y + 8 y22y8=0y^2 - 2y - 8 = 0 (y4)(y+2)=0(y-4)(y+2)=0

Thus, the intersection limits are y=2y=-2 and y=4y=4.

Now,

xline=y2+4x_{\text{line}} = \frac{y}{2} + 4 xparabola=y24+2x_{\text{parabola}} = \frac{y^2}{4} + 2

So,

A=24(xlinexparabola)dyA = \int_{-2}^{4} (x_{\text{line}} - x_{\text{parabola}}) \, dy A=24(y2+4y242)dyA = \int_{-2}^{4} \left(\frac{y}{2}+4-\frac{y^2}{4}-2\right) \, dy A=24(y24+y2+2)dyA = \int_{-2}^{4} \left(-\frac{y^2}{4} + \frac{y}{2} + 2\right) \, dy

Now evaluate termwise:

24y24dy=6\int_{-2}^{4} -\frac{y^2}{4} \, dy = -6 24y2dy=3\int_{-2}^{4} \frac{y}{2} \, dy = 3 242dy=12\int_{-2}^{4} 2 \, dy = 12

Hence,

A=6+3+12=9A = -6 + 3 + 12 = 9

Therefore, the enclosed area is 99 square units, so the correct option is B.

Common mistakes

  • Taking area as (yupperylower)dx\int (y_{\text{upper}}-y_{\text{lower}}) \, dx directly is incorrect here because the curves are more naturally expressed as xx in terms of yy. Write both curves as x=f(y)x=f(y) and integrate with respect to yy.

  • Using the wrong order inside the integrand gives a negative area. In the interval 2y4-2 \le y \le 4, the line is the right curve and the parabola is the left curve, so use xlinexparabolax_{\text{line}} - x_{\text{parabola}}.

  • Finding intersection points only in terms of xx and then mixing them with a dydy integral causes incorrect limits. Since the integration is with respect to yy, the limits must be y=2y=-2 and y=4y=4.

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