MCQMediumJEE 2025Equation of Line in 3D

JEE Mathematics 2025 Question with Solution

If the image of the point P(1,0,3)P(1, 0, 3) in the line joining the points A(4,7,1)A(4, 7, 1) and B(3,5,3)B(3, 5, 3) is Q(α,β,γ)Q(\alpha, \beta, \gamma), then α+β+γ\alpha + \beta + \gamma is equal to:

  • A

    473\frac{47}{3}

  • B

    463\frac{46}{3}

  • C

    1818

  • D

    1313

Answer

Correct answer:B

Step-by-step solution

Standard Method

Given: The point is P(1,0,3)P(1,0,3) and the line passes through A(4,7,1)A(4,7,1) and B(3,5,3)B(3,5,3).

Find: If the image of PP in the given line is Q(α,β,γ)Q(\alpha,\beta,\gamma), find α+β+γ\alpha+\beta+\gamma.

The image of a point in a line is obtained by reflecting the point across the line. So first find the foot of the perpendicular from PP to the line, and then use the midpoint relation.

The direction vector of the line is

d=BA=(34)i^+(57)j^+(31)k^=i^2j^+2k^\vec d = \vec B - \vec A = (3-4)\hat i + (5-7)\hat j + (3-1)\hat k = -\hat i - 2\hat j + 2\hat k

Hence the vector equation of the line through AA is

r=(4i^+7j^+k^)+λ(i^2j^+2k^)\vec r = (4\hat i + 7\hat j + \hat k) + \lambda(-\hat i - 2\hat j + 2\hat k)

So any point MM on the line is

M(4λ,72λ,1+2λ)M(4-\lambda, 7-2\lambda, 1+2\lambda)

Now,

PM=((4λ)1)i^+((72λ)0)j^+((1+2λ)3)k^\vec{PM} = \big((4-\lambda)-1\big)\hat i + \big((7-2\lambda)-0\big)\hat j + \big((1+2\lambda)-3\big)\hat k

that is,

PM=(3λ)i^+(72λ)j^+(2+2λ)k^\vec{PM} = (3-\lambda)\hat i + (7-2\lambda)\hat j + (-2+2\lambda)\hat k

Since PMPM is perpendicular to the line, we use

PMd=0\vec{PM} \cdot \vec d = 0

Therefore,

(3λ)(1)+(72λ)(2)+(2+2λ)(2)=0(3-\lambda)(-1) + (7-2\lambda)(-2) + (-2+2\lambda)(2) = 0 3+λ14+4λ4+4λ=0-3 + \lambda - 14 + 4\lambda - 4 + 4\lambda = 0 9λ21=0    λ=739\lambda - 21 = 0 \implies \lambda = \frac{7}{3}

Substituting λ=73\lambda=\frac{7}{3} in the coordinates of MM,

xM=473=53x_M = 4-\frac{7}{3} = \frac{5}{3} yM=72(73)=73y_M = 7-2\left(\frac{7}{3}\right) = \frac{7}{3} zM=1+2(73)=173z_M = 1+2\left(\frac{7}{3}\right) = \frac{17}{3}

Thus, the foot of the perpendicular is

M(53,73,173)M\left(\frac{5}{3}, \frac{7}{3}, \frac{17}{3}\right)

Since MM is the midpoint of PQPQ,

(53,73,173)=(1+α2,β2,3+γ2)\left(\frac{5}{3}, \frac{7}{3}, \frac{17}{3}\right) = \left(\frac{1+\alpha}{2}, \frac{\beta}{2}, \frac{3+\gamma}{2}\right)

Now solve coordinate-wise:

1+α2=53    α=73\frac{1+\alpha}{2} = \frac{5}{3} \implies \alpha = \frac{7}{3} β2=73    β=143\frac{\beta}{2} = \frac{7}{3} \implies \beta = \frac{14}{3} 3+γ2=173    γ=253\frac{3+\gamma}{2} = \frac{17}{3} \implies \gamma = \frac{25}{3}

So,

α+β+γ=73+143+253=463\alpha + \beta + \gamma = \frac{7}{3} + \frac{14}{3} + \frac{25}{3} = \frac{46}{3}

Therefore, the correct option is B, and α+β+γ=463\alpha+\beta+\gamma=\frac{46}{3}.

Using reflection through the foot of perpendicular

Given: P(1,0,3)P(1,0,3) and line through A(4,7,1)A(4,7,1), B(3,5,3)B(3,5,3).

Find: The value of α+β+γ\alpha+\beta+\gamma where Q(α,β,γ)Q(\alpha,\beta,\gamma) is the image of PP in the line.

The key idea is that reflection in a line makes the line the perpendicular bisector of segment PQPQ in 3D, so the foot point on the line becomes the midpoint of PP and QQ.

Use the line through AA in parametric form. Its direction vector is

(1,2,2)(-1,-2,2)

Hence a general point on the line is

(4λ,72λ,1+2λ)(4-\lambda, 7-2\lambda, 1+2\lambda)

Call this point MM.

For MM to be the foot of the perpendicular from P(1,0,3)P(1,0,3), vector PM\vec{PM} must be perpendicular to the direction vector (1,2,2)(-1,-2,2). This gives one equation in λ\lambda, which yields

λ=73\lambda=\frac{7}{3}

Therefore,

M=(53,73,173)M=\left(\frac{5}{3},\frac{7}{3},\frac{17}{3}\right)

Now reflect PP about midpoint MM using

q=2mp\vec q = 2\vec m - \vec p

So,

Q=2(53,73,173)(1,0,3)Q = 2\left(\frac{5}{3},\frac{7}{3},\frac{17}{3}\right) - (1,0,3) Q=(1031,1430,3433)Q = \left(\frac{10}{3}-1, \frac{14}{3}-0, \frac{34}{3}-3\right) Q=(73,143,253)Q = \left(\frac{7}{3}, \frac{14}{3}, \frac{25}{3}\right)

Hence,

α+β+γ=73+143+253=463\alpha+\beta+\gamma = \frac{7}{3}+\frac{14}{3}+\frac{25}{3} = \frac{46}{3}

Therefore, the required sum is 463\frac{46}{3}.

Common mistakes

  • A common mistake is to use the midpoint formula directly between AA and BB. That is wrong because the image of PP is taken in the line through AA and BB, not in the segment midpoint of ABAB. First find the foot of the perpendicular from PP to the line.

  • Students often take the direction vector incorrectly as AB\vec A-\vec B or make sign errors in coordinates. Although a scalar multiple also represents the same line, the dot product equation must then be formed consistently.

  • Another mistake is to forget that the foot point MM is the midpoint of PP and QQ after reflection. Using Q=MPQ=M-P is incorrect. The correct relation is

    q=2mp\vec q = 2\vec m - \vec p

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