MCQMediumJEE 2024Linear Differential Equations

JEE Mathematics 2024 Question with Solution

The differential equation, whose general solution is y=c1f(x)+c2y = c_1 f(x) + c_2, where c1c_1 and c2c_2 are arbitrary constants, is:

  • A

    (8ex1)d2ydx2+dydx=0(8e^x - 1) \frac{d^2y}{dx^2} + \frac{dy}{dx} = 0

  • B

    (8ex+1)d2ydx2dydx=0(8e^x + 1) \frac{d^2y}{dx^2} - \frac{dy}{dx} = 0

  • C

    (8ex+1)d2ydx2+dydx=0(8e^x + 1) \frac{d^2y}{dx^2} + \frac{dy}{dx} = 0

  • D

    (8ex1)d2ydx2dydx=0(8e^x - 1) \frac{d^2y}{dx^2} - \frac{dy}{dx} = 0

Answer

Correct answer:C

Step-by-step solution

Standard Method

Given: The general solution is y=c1f(x)+c2y = c_1 f(x) + c_2.

Also, from the solution data,

0af(x)dx=ea+4a2+a1\int_0^a f(x) \, dx = e^{-a} + 4a^2 + a - 1

Find: The differential equation satisfied by yy.

Differentiate the given integral with respect to aa:

f(a)=dda(ea+4a2+a1)=ea+8a+1f(a) = \frac{d}{da}\left(e^{-a} + 4a^2 + a - 1\right) = -e^{-a} + 8a + 1

So,

f(x)=ex+8x+1f(x) = -e^{-x} + 8x + 1

Now differentiate:

f(x)=ex+8f'(x) = e^{-x} + 8

and

f(x)=exf''(x) = -e^{-x}

Since

y=c1f(x)+c2y = c_1 f(x) + c_2

we get

dydx=c1f(x)\frac{dy}{dx} = c_1 f'(x)

and

d2ydx2=c1f(x)\frac{d^2y}{dx^2} = c_1 f''(x)

Substitute f(x)=ex+8f'(x) = e^{-x} + 8 and f(x)=exf''(x) = -e^{-x} into the expression

(8ex+1)d2ydx2+dydx(8e^x + 1)\frac{d^2y}{dx^2} + \frac{dy}{dx}

Then

(8ex+1)c1f(x)+c1f(x)(8e^x + 1) c_1 f''(x) + c_1 f'(x) =c1[(8ex+1)(ex)+(ex+8)]= c_1 \left[(8e^x + 1)(-e^{-x}) + (e^{-x} + 8)\right] =c1[8ex+ex+8]=0= c_1 \left[-8 - e^{-x} + e^{-x} + 8\right] = 0

Therefore, the required differential equation is

(8ex+1)d2ydx2+dydx=0(8e^x + 1)\frac{d^2y}{dx^2} + \frac{dy}{dx} = 0

Hence, the correct option is C.

Differentiate the given integral first

Given:

0af(x)dx=ea+4a2+a1\int_0^a f(x) \, dx = e^{-a} + 4a^2 + a - 1

and the family of solutions is y=c1f(x)+c2y = c_1 f(x) + c_2.

Find: Which option gives the correct differential equation.

Using the Fundamental Theorem of Calculus,

f(a)=dda0af(x)dxf(a) = \frac{d}{da} \int_0^a f(x) \, dx

So,

f(a)=dda(ea+4a2+a1)=ea+8a+1f(a) = \frac{d}{da}(e^{-a} + 4a^2 + a - 1) = -e^{-a} + 8a + 1

Replacing aa by xx,

f(x)=ex+8x+1f(x) = -e^{-x} + 8x + 1

Then,

f(x)=ex+8,f'(x) = e^{-x} + 8, f(x)=exf''(x) = -e^{-x}

Now for

y=c1f(x)+c2,y = c_1 f(x) + c_2,

we have

y=c1f(x),y=c1f(x)y' = c_1 f'(x), \qquad y'' = c_1 f''(x)

Test option C:

(8ex+1)y+y=0(8e^x + 1)y'' + y' = 0

Substituting,

(8ex+1)c1f(x)+c1f(x)=0(8e^x + 1)c_1 f''(x) + c_1 f'(x) = 0 c1[(8ex+1)(ex)+(ex+8)]=0c_1\left[(8e^x + 1)(-e^{-x}) + (e^{-x} + 8)\right] = 0 c1(8ex+ex+8)=0c_1(-8 - e^{-x} + e^{-x} + 8) = 0 0=00 = 0

Thus the family y=c1f(x)+c2y = c_1 f(x) + c_2 satisfies option C. Therefore, the correct differential equation is (8ex+1)d2ydx2+dydx=0(8e^x + 1)\frac{d^2y}{dx^2} + \frac{dy}{dx} = 0.

Common mistakes

  • Differentiating 0af(x)dx\int_0^a f(x) \, dx incorrectly with respect to aa. By the Fundamental Theorem of Calculus, it becomes f(a)f(a), not an integral again. First obtain f(a)f(a) correctly, then proceed.

  • Forgetting that c2c_2 is a constant. When differentiating y=c1f(x)+c2y = c_1 f(x) + c_2, the derivative of c2c_2 is 00. So y=c1f(x)y' = c_1 f'(x) and y=c1f(x)y'' = c_1 f''(x).

  • Making a sign error while differentiating ex-e^{-x} or exe^{-x}. Since ddx(ex)=ex\frac{d}{dx}(e^{-x}) = -e^{-x}, it follows that ddx(ex)=ex\frac{d}{dx}(-e^{-x}) = e^{-x}. Track the negative sign carefully.

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