MCQMediumJEE 2025Definite Integrals

JEE Mathematics 2025 Question with Solution

Scanned mathematics section image containing the definite integral question and its four answer options from JEE Main paper.

MATHEMATICS SECTION-A

The value of e2e41x(e((logex)2+1)1e((logex)2+1)1+e((6logex)2+1)1)dx\int_{e^2}^{e^4} \frac{1}{x} \left( \frac{e^{\left( (\log_e x)^2 +1 \right)^{-1}}}{e^{\left( (\log_e x)^2 +1 \right)^{-1}} + e^{\left( (6-\log_e x)^2 +1 \right)^{-1}}} \right) dx is:

  • A

    log2\log 2

  • B

    22

  • C

    11

  • D

    e2e^2

Answer

Correct answer:C

Step-by-step solution

Standard Method

Given:

I=e2e41x(e((logex)2+1)1e((logex)2+1)1+e((6logex)2+1)1)dxI=\int_{e^2}^{e^4} \frac{1}{x} \left( \frac{e^{\left( (\log_e x)^2 +1 \right)^{-1}}}{e^{\left( (\log_e x)^2 +1 \right)^{-1}} + e^{\left( (6-\log_e x)^2 +1 \right)^{-1}}} \right) dx

Find: The value of the integral.

Let

t=logext=\log_e x

Then

dt=1xdxdt=\frac{1}{x}dx

When x=e2x=e^2, t=2t=2 and when x=e4x=e^4, t=4t=4.

So the integral becomes

I=24e(t2+1)1e(t2+1)1+e((6t)2+1)1dtI=\int_{2}^{4} \frac{e^{\left( t^2 + 1 \right)^{-1}}}{e^{\left( t^2 + 1 \right)^{-1}} + e^{\left( (6-t)^2 + 1 \right)^{-1}}} \, dt

Now use the symmetry substitution

t6tt \mapsto 6-t

Then the same integral can be written as

I=24e((6t)2+1)1e((6t)2+1)1+e(t2+1)1dtI=\int_{2}^{4} \frac{e^{\left( (6-t)^2 + 1 \right)^{-1}}}{e^{\left( (6-t)^2 + 1 \right)^{-1}} + e^{\left( t^2 + 1 \right)^{-1}}} \, dt

Adding the two expressions,

2I=24(e(t2+1)1e(t2+1)1+e((6t)2+1)1+e((6t)2+1)1e((6t)2+1)1+e(t2+1)1)dt=241dt=42=2\begin{aligned} 2I &= \int_{2}^{4} \left( \frac{e^{\left( t^2 + 1 \right)^{-1}}}{e^{\left( t^2 + 1 \right)^{-1}} + e^{\left( (6-t)^2 + 1 \right)^{-1}}} + \frac{e^{\left( (6-t)^2 + 1 \right)^{-1}}}{e^{\left( (6-t)^2 + 1 \right)^{-1}} + e^{\left( t^2 + 1 \right)^{-1}}} \right) dt \\ &= \int_{2}^{4} 1 \, dt \\ &= 4-2 = 2 \end{aligned}

Hence,

I=1I=1

Therefore, the correct option is C.

Symmetry Trick

Given: The integrand has the form

f(t)=A(t)A(t)+A(6t)f(t)=\frac{A(t)}{A(t)+A(6-t)}

after putting t=logext=\log_e x.

Find: The value of the definite integral.

With

t=logex,dt=1xdxt=\log_e x, \qquad dt=\frac{1}{x}dx

we get

I=24f(t)dtI=\int_2^4 f(t) \, dt

where

f(t)=e(t2+1)1e(t2+1)1+e((6t)2+1)1f(t)=\frac{e^{\left( t^2 + 1 \right)^{-1}}}{e^{\left( t^2 + 1 \right)^{-1}}+e^{\left( (6-t)^2 + 1 \right)^{-1}}}

Now observe that

f(6t)=e((6t)2+1)1e((6t)2+1)1+e(t2+1)1f(6-t)=\frac{e^{\left( (6-t)^2 + 1 \right)^{-1}}}{e^{\left( (6-t)^2 + 1 \right)^{-1}}+e^{\left( t^2 + 1 \right)^{-1}}}

So,

f(t)+f(6t)=1f(t)+f(6-t)=1

For an integral over [2,4][2,4], this symmetry gives

2I=24(f(t)+f(6t))dt=241dt=22I=\int_2^4 \big(f(t)+f(6-t)\big) \, dt=\int_2^4 1 \, dt=2

Thus,

I=1I=1

Therefore, the value of the integral is 11.

Common mistakes

  • Using t=logext=\log_e x but forgetting that dt=1xdxdt=\frac{1}{x}dx. This is wrong because the factor 1x\frac{1}{x} is essential for the substitution. Replace the entire term 1xdx\frac{1}{x}dx by dtdt and also change the limits.

  • Treating the integrand as constant 12\frac{1}{2} without first establishing the symmetry. This is wrong because the numerator and denominator are not individually equal for every tt. First show that f(t)+f(6t)=1f(t)+f(6-t)=1, then use definite-integral symmetry.

  • Not changing the limits after substitution and continuing with xx-limits in the tt-integral. This mixes two variables incorrectly. After t=logext=\log_e x, the limits must become 22 and 44.

Practice more Definite Integrals questions

Get unlimited AI-adaptive practice, mastery tracking, and an AI tutor that explains every step — free to start.

Related questions