MCQMediumJEE 2026Applications of Integrals (Area)

JEE Mathematics 2026 Question with Solution

Let the line x=1x = -1 divide the area of the region {(x,y):1+x2y3x}\{(x,y): 1 + x^2 \le y \le 3 - x\} in the ratio m:nm:n, where gcd(m,n)=1\gcd(m,n)=1. Then m+nm+n is equal to

  • A

    2727

  • B

    2626

  • C

    2525

  • D

    2828

Answer

Correct answer:A

Step-by-step solution

Standard Method

Given: The region is bounded by y=1+x2y = 1 + x^2 and y=3xy = 3 - x, and the line x=1x = -1 divides it into two parts.

Find: If the ratio is m:nm:n in lowest terms, find m+nm+n.

First find the intersection points of the two curves:

1+x2=3x1 + x^2 = 3 - x x2+x2=0x^2 + x - 2 = 0 (x+2)(x1)=0(x+2)(x-1)=0

So the region extends from x=2x=-2 to x=1x=1.

On this interval, the upper curve is y=3xy=3-x and the lower curve is y=1+x2y=1+x^2. Hence the vertical strip height is

(3x)(1+x2)=2xx2(3-x) - (1+x^2) = 2-x-x^2

The area to the left of x=1x=-1 is

21(2xx2)dx\int_{-2}^{-1} (2-x-x^2) \, dx

and the area to the right of x=1x=-1 is

11(2xx2)dx\int_{-1}^{1} (2-x-x^2) \, dx

An antiderivative is

(2xx2)dx=2xx22x33\int (2-x-x^2) \, dx = 2x - \frac{x^2}{2} - \frac{x^3}{3}

Now evaluate the left part:

[2xx22x33]21\left[2x - \frac{x^2}{2} - \frac{x^3}{3}\right]_{-2}^{-1}

At x=1x=-1, the value is 212+13=136-2 - \frac{1}{2} + \frac{1}{3} = -\frac{13}{6}. At x=2x=-2, the value is 42+83=103-4 - 2 + \frac{8}{3} = -\frac{10}{3}. Therefore,

21(2xx2)dx=136(103)=76\int_{-2}^{-1} (2-x-x^2) \, dx = -\frac{13}{6} - \left(-\frac{10}{3}\right) = \frac{7}{6}

Now evaluate the right part:

[2xx22x33]11\left[2x - \frac{x^2}{2} - \frac{x^3}{3}\right]_{-1}^{1}

At x=1x=1, the value is 21213=762 - \frac{1}{2} - \frac{1}{3} = \frac{7}{6}. At x=1x=-1, the value is 136-\frac{13}{6}. Therefore,

11(2xx2)dx=76(136)=206=103\int_{-1}^{1} (2-x-x^2) \, dx = \frac{7}{6} - \left(-\frac{13}{6}\right) = \frac{20}{6} = \frac{10}{3}

Hence the ratio of left area to right area is

7/610/3=720\frac{7/6}{10/3} = \frac{7}{20}

So the two parts are in the ratio 7:207:20. Therefore, taking m:n=20:7m:n = 20:7 or 7:207:20 changes only the order, but in either case

m+n=27m+n = 27

The solution lists Option B but its own computation ends at 2727. The worked integrals support m+n=27m+n=27, so the correct option is A.

Area on each side of the vertical line

The bounded region exists where the line lies above the parabola. Solve

3x1+x23-x \ge 1+x^2

which reduces to

x2+x20x^2 + x - 2 \le 0

with roots 2-2 and 11. So the enclosed part is between these two xx-values.

Because the dividing line is vertical, split the area at x=1x=-1. Then use upper minus lower in each definite integral:

Area=(upper curvelower curve)dx\text{Area} = \int (\text{upper curve} - \text{lower curve}) \, dx

Thus,

A1=21(2xx2)dx=76,A2=11(2xx2)dx=103A_1 = \int_{-2}^{-1} (2-x-x^2) \, dx = \frac{7}{6}, \qquad A_2 = \int_{-1}^{1} (2-x-x^2) \, dx = \frac{10}{3}

Multiply both by 66 to write the ratio without fractions:

A1:A2=7:20A_1 : A_2 = 7 : 20

Hence the sum of the coprime terms is

7+20=277+20=27

Common mistakes

  • Taking the ratio in the wrong order. The line x=1x=-1 creates a left part and a right part, so you must identify clearly which one is called mm and which one is called nn before forming the ratio. Even if the order is reversed, the final sum here remains the same, but this is not always true.

  • Using the curves in the wrong order inside the integral. The area between curves is upper minus lower, so the integrand is (3x)(1+x2)(3-x) - (1+x^2). Reversing this gives a negative value and can lead to confusion.

  • Computing the antiderivative correctly but substituting limits incorrectly at negative values. Terms like x33-\frac{x^3}{3} change sign carefully when x=1x=-1 or x=2x=-2. Write the boundary values separately before subtracting.

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