MCQMediumJEE 2024Basics: Distance, Section Formula, Locus

JEE Mathematics 2024 Question with Solution

Let alpha, beta, gamma, delta Z\in \mathbb{Z} and let A(α,β)A(\alpha, \beta), B(1,0)B(1, 0), C(γ,δ)C(\gamma, \delta), and D(1,2)D(1, 2) be the vertices of a parallelogram ABCD. If AB=10AB = \sqrt{10} and the points A and C lie on the line 3y=2x+13y = 2x + 1, then 2(α+β+γ+δ)2(\alpha + \beta + \gamma + \delta) is equal to:

  • A

    1010

  • B

    55

  • C

    1212

  • D

    88

Answer

Correct answer:D

Step-by-step solution

Standard Method

Given: A(α,β)A(\alpha, \beta), B(1,0)B(1,0), C(γ,δ)C(\gamma, \delta), D(1,2)D(1,2) are vertices of a parallelogram, AB=10AB=\sqrt{10}, and points AA and CC lie on 3y=2x+13y=2x+1.

Find: 2(α+β+γ+δ)2(\alpha+\beta+\gamma+\delta).

Since AA and CC lie on the line, we have

3β=2α+13\beta = 2\alpha + 1

and

3δ=2γ+13\delta = 2\gamma + 1

Also, from AB=10AB=\sqrt{10},

(α1)2+β2=10\sqrt{(\alpha-1)^2 + \beta^2} = \sqrt{10}

So,

(α1)2+β2=10(\alpha-1)^2 + \beta^2 = 10

Now use the parallelogram property. The vectors are

AB=(1α,β)\overrightarrow{AB} = (1-\alpha,-\beta)

and

CD=(1γ,2δ)\overrightarrow{CD} = (1-\gamma,2-\delta)

For a parallelogram,

AB=CD\overrightarrow{AB} = \overrightarrow{CD}

Hence,

1α=1γ1-\alpha = 1-\gamma

and

β=2δ-\beta = 2-\delta

Therefore,

α=γ\alpha = \gamma

and

β+δ=2\beta + \delta = 2

Using α=γ\alpha=\gamma in the two line equations gives

3β=2α+13\beta = 2\alpha + 1

and

3δ=2α+13\delta = 2\alpha + 1

So,

3β=3δ3\beta = 3\delta

which implies

β=δ\beta = \delta

Together with β+δ=2\beta+\delta=2, we get

β=1,δ=1\beta = 1, \quad \delta = 1

Now from

3β=2α+13\beta = 2\alpha + 1

we obtain

3(1)=2α+13(1) = 2\alpha + 1

so

α=1\alpha = 1

Thus,

γ=1\gamma = 1

Finally,

2(α+β+γ+δ)=2(1+1+1+1)=82(\alpha+\beta+\gamma+\delta) = 2(1+1+1+1) = 8

Therefore, the correct option is D.

Using midpoint of diagonals

Given: A(α,β)A(\alpha, \beta), B(1,0)B(1,0), C(γ,δ)C(\gamma, \delta), D(1,2)D(1,2) form a parallelogram.

Find: 2(α+β+γ+δ)2(\alpha+\beta+\gamma+\delta).

In a parallelogram, diagonals bisect each other. So the midpoint of ACAC equals the midpoint of BDBD.

For diagonal BDBD, the midpoint is

(1+12,0+22)=(1,1)\left(\frac{1+1}{2}, \frac{0+2}{2}\right) = (1,1)

Hence, for diagonal ACAC,

α+γ2=1\frac{\alpha+\gamma}{2} = 1

and

β+δ2=1\frac{\beta+\delta}{2} = 1

So,

α+γ=2,β+δ=2\alpha+\gamma = 2, \quad \beta+\delta = 2

Therefore,

2(α+β+γ+δ)=2((α+γ)+(β+δ))=2(2+2)=82(\alpha+\beta+\gamma+\delta) = 2\big((\alpha+\gamma)+(\beta+\delta)\big) = 2(2+2) = 8

This directly gives the correct option as D.

The shortcut works because the required expression depends only on the sums α+γ\alpha+\gamma and β+δ\beta+\delta, which are obtained immediately from the midpoint property.

Common mistakes

  • Using only the distance condition AB=10AB=\sqrt{10} and ignoring the parallelogram property. That is incomplete because the required sum depends on relations among all four vertices. Use the diagonal or vector property of a parallelogram as well.

  • Writing the midpoint condition incorrectly for the diagonals. In a parallelogram, diagonals bisect each other, so the midpoint of ACAC must equal the midpoint of BDBD. Do not equate endpoints or side lengths instead of midpoints.

  • From β=2δ-\beta = 2-\delta, concluding δ=2β\delta=2-\beta but then forgetting that this means β+δ=2\beta+\delta=2. Keep the sign carefully while rearranging vector equations.

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