NVAMediumJEE 2025Differentiability

JEE Mathematics 2025 Question with Solution

Let the function, f(x)={3ax22,x<1a2+bx,x1f(x) = \begin{cases} -3ax^2 - 2, & x < 1 \\ a^2 + bx, & x \geq 1 \end{cases} Be differentiable for all xRx \in \mathbb{R}, where a>1a > 1, bRb \in \mathbb{R}. If the area of the region enclosed by y=f(x)y = f(x) and the line y=20y = -20 is α+β3\alpha + \beta\sqrt{3}, where α,βZ\alpha, \beta \in \mathbb{Z}, then the value of α+β\alpha + \beta is:

Answer

Correct answer:34

Step-by-step solution

Standard Method

Given:

f(x)={3ax22,x<1a2+bx,x1f(x)=\begin{cases} -3ax^2-2, & x<1 \\ a^2+bx, & x\geq 1 \end{cases}

The function is differentiable for all xRx \in \mathbb{R} with a>1a>1.

Find: The value of α+β\alpha+\beta if the enclosed area with the line y=20y=-20 is α+β3\alpha+\beta\sqrt{3}.

For differentiability at x=1x=1, the function must be continuous and must have equal derivatives from both sides.

Continuity at x=1x=1 gives

3a(1)22=a2+b-3a(1)^2-2=a^2+b

so

a2+b=3a2a^2+b=-3a-2

For x<1x<1,

f(x)=6axf'(x)=-6ax

and at x=1x=1 the left derivative is

6a-6a

For x1x\geq 1,

f(x)=bf'(x)=b

Hence differentiability gives

b=6ab=-6a

Substitute this into the continuity equation:

a26a=3a2a^2-6a=-3a-2 a23a+2=0a^2-3a+2=0 (a1)(a2)=0(a-1)(a-2)=0

Since a>1a>1, we get

a=2a=2

and therefore

b=12b=-12

So the function becomes

f(x)={6x22,x<1412x,x1f(x)=\begin{cases} -6x^2-2, & x<1 \\ 4-12x, & x\geq 1 \end{cases}

Now find the intersections with the line y=20y=-20.

For x<1x<1,

6x22=20-6x^2-2=-20 x2=3x^2=3 x=±3x=\pm\sqrt{3}

Only x=3x=-\sqrt{3} satisfies x<1x<1.

For x1x\geq 1,

412x=204-12x=-20 x=2x=2

Therefore the enclosed region lies from x=3x=-\sqrt{3} to x=2x=2, split at x=1x=1.

Area

=31(f(x)+20)dx+12(f(x)+20)dx=\int_{-\sqrt{3}}^{1}(f(x)+20)\,dx+\int_{1}^{2}(f(x)+20)\,dx

For x[3,1]x\in[-\sqrt{3},1],

f(x)+20=6x22+20=6x2+18f(x)+20=-6x^2-2+20=-6x^2+18

So

31(6x2+18)dx\int_{-\sqrt{3}}^{1}(-6x^2+18)\,dx =[2x3+18x]31=\left[-2x^3+18x\right]_{-\sqrt{3}}^{1} =(2+18)(2(33)+18(3))=(-2+18)-\left(-2(-3\sqrt{3})+18(-\sqrt{3})\right) =16(63183)=16-(6\sqrt{3}-18\sqrt{3}) =16+123=16+12\sqrt{3}

For x[1,2]x\in[1,2],

f(x)+20=412x+20=2412xf(x)+20=4-12x+20=24-12x

So

12(2412x)dx\int_{1}^{2}(24-12x)\,dx =[24x6x2]12=\left[24x-6x^2\right]_{1}^{2} =(4824)(246)=(48-24)-(24-6) =2418=6=24-18=6

Hence total area is

(16+123)+6=22+123(16+12\sqrt{3})+6=22+12\sqrt{3}

So

α=22,β=12\alpha=22, \qquad \beta=12

and

α+β=34\alpha+\beta=34

Therefore, the required value is 3434.

Using continuity, differentiability, and bounded intersections

Given: A piecewise function and the condition that it is differentiable everywhere.

Find: The enclosed area expression and then α+β\alpha+\beta.

The first step is to determine the constants by matching both function value and derivative at the joining point x=1x=1.

From continuity:

3a2=a2+b-3a-2=a^2+b

From differentiability:

b=6ab=-6a

Substituting,

a26a=3a2a^2-6a=-3a-2 a23a+2=0a^2-3a+2=0 (a1)(a2)=0(a-1)(a-2)=0

Since a>1a>1, take

a=2a=2

and hence

b=12b=-12

Thus,

f(x)={6x22,x<1412x,x1f(x)=\begin{cases} -6x^2-2, & x<1 \\ 4-12x, & x\geq 1 \end{cases}

Now the phrase "area of the region enclosed" means we must locate the finite bounded region between the curve and the line y=20y=-20.

For the left branch:

6x22=20-6x^2-2=-20 x2=3x^2=3

This gives x=±3x=\pm\sqrt{3}, but only x=3x=-\sqrt{3} belongs to the branch x<1x<1 in the bounded region connected to the join.

For the right branch:

412x=204-12x=-20 x=2x=2

Hence the bounded region runs from x=3x=-\sqrt{3} to x=2x=2.

The area above the line y=20y=-20 is obtained by integrating f(x)(20)=f(x)+20f(x)-(-20)=f(x)+20.

Left part:

A1=31(6x2+18)dxA_1=\int_{-\sqrt{3}}^{1}(-6x^2+18)\,dx A1=[2x3+18x]31A_1=\left[-2x^3+18x\right]_{-\sqrt{3}}^{1} A1=16+123A_1=16+12\sqrt{3}

Right part:

A2=12(2412x)dxA_2=\int_{1}^{2}(24-12x)\,dx A2=[24x6x2]12=6A_2=\left[24x-6x^2\right]_{1}^{2}=6

Total area:

A=A1+A2=22+123A=A_1+A_2=22+12\sqrt{3}

Therefore,

α=22,β=12\alpha=22, \quad \beta=12

so

α+β=34\alpha+\beta=34

The correct numerical answer is 3434.

Common mistakes

  • Using only continuity at x=1x=1 and forgetting differentiability. That gives one equation but not enough to determine both aa and bb. You must match both the function values and the derivatives at the joining point.

  • Taking both roots x=±3x=\pm\sqrt{3} as valid on the left branch without checking the domain condition x<1x<1. The branch restriction matters, so only the point consistent with the piecewise definition should be used for the enclosed region.

  • Integrating the right branch up to \infty. The question asks for the enclosed bounded region with the line y=20y=-20, so the upper limit is the intersection point x=2x=2, not infinity.

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