NVAMediumJEE 2024Conic Sections (Parabola, Ellipse, Hyperbola)

JEE Mathematics 2024 Question with Solution

The area of the region enclosed by the parabola (y2)2=x1(y-2)^2 = x-1, the line x2y+4=0x-2y+4 = 0, and the positive coordinate axes is:

Answer

Correct answer:5

Step-by-step solution

Standard Method

Given: The parabola is (y2)2=x1(y-2)^2 = x-1 and the line is x2y+4=0x-2y+4 = 0. The region lies in the first quadrant and is enclosed with the positive coordinate axes.

Find: The area of the enclosed region.

Write both curves as xx in terms of yy:

x=(y2)2+1x = (y-2)^2 + 1 x=2y4x = 2y - 4

Now find the key intersection points shown in the solution.

Intersection of parabola and line:

(y2)2+1=2y4(y-2)^2 + 1 = 2y - 4 y24y+4+1=2y4y^2 - 4y + 4 + 1 = 2y - 4 y26y+9=0y^2 - 6y + 9 = 0 (y3)2=0(y-3)^2 = 0

So,

y=3,x=2y = 3,\, x = 2

Hence the curves touch at (2,3)(2,3).

Intersection of the line with the positive yy-axis:

x=0    2y4=0    y=2x = 0 \implies 2y - 4 = 0 \implies y = 2

So the point is (0,2)(0,2).

Intersection of the parabola with the positive xx-axis:

y=0    x=(02)2+1=5y = 0 \implies x = (0-2)^2 + 1 = 5

So the point is (5,0)(5,0).

The area is split into two parts.

For 0y20 \le y \le 2, the region is between the parabola and the yy-axis:

A1=02(((y2)2+1)0)dyA_1 = \int_0^2 \left(((y-2)^2 + 1) - 0\right) \, dy A1=02(y24y+5)dyA_1 = \int_0^2 (y^2 - 4y + 5) \, dy A1=[y332y2+5y]02A_1 = \left[ \frac{y^3}{3} - 2y^2 + 5y \right]_0^2 A1=838+10=143A_1 = \frac{8}{3} - 8 + 10 = \frac{14}{3}

For 2y32 \le y \le 3, the region is between the parabola and the line:

A2=23(((y2)2+1)(2y4))dyA_2 = \int_2^3 \left(((y-2)^2 + 1) - (2y - 4)\right) \, dy A2=23(y26y+9)dyA_2 = \int_2^3 (y^2 - 6y + 9) \, dy A2=23(y3)2dyA_2 = \int_2^3 (y-3)^2 \, dy A2=[(y3)33]23=13A_2 = \left[ \frac{(y-3)^3}{3} \right]_2^3 = \frac{1}{3}

Therefore,

A=A1+A2=143+13=5A = A_1 + A_2 = \frac{14}{3} + \frac{1}{3} = 5

Therefore, the area of the required region is 55 square units.

Using the extracted approach

Given: The parabola is (y2)2=x1(y-2)^2 = x-1 and the line is x2y+4=0x-2y+4 = 0.

Find: The enclosed area in the first quadrant.

From the extracted working,

(y2)2=x1    y2=x1(y - 2)^2 = x - 1 \implies y - 2 = \sqrt{x - 1}

and

x2y+4=0    y=x+42x - 2y + 4 = 0 \implies y = \frac{x + 4}{2}

Equating them,

x+42=x1+2\frac{x+4}{2} = \sqrt{x-1} + 2

Rearranging and squaring gives

(x2)2=0(x-2)^2 = 0

Hence,

x=2x = 2

and then

y=2+42=3y = \frac{2+4}{2} = 3

So the intersection point is (2,3)(2,3).

The extracted solution concludes the area evaluates to 55. The more geometrically consistent setup is to integrate with respect to yy as shown in the standard method above, which gives the same final value.

Therefore, the required area is 55.

Common mistakes

  • Taking the line as y=x42y = \frac{x-4}{2} instead of y=x+42y = \frac{x+4}{2}. This changes the intersection point and the entire region. Rearrange x2y+4=0x-2y+4=0 carefully to get x=2y4x = 2y-4 or equivalently y=x+42y = \frac{x+4}{2}.

  • Using a single integral without splitting the region. The left boundary changes at y=2y=2 from the yy-axis to the line, so the area must be divided into two parts.

  • Integrating with respect to xx using the upper branch only. The parabola is better handled as x=(y2)2+1x = (y-2)^2 + 1 here; otherwise the region description becomes incomplete or incorrect.

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