NVAMediumJEE 2023Equation of Line in 3D

JEE Mathematics 2023 Question with Solution

Let a line L pass through the point P(2,3,1)P(2, 3, 1) and be parallel to the line x+3y2z2=0x + 3y - 2z - 2 = 0 i.e. xy+2z=0x - y + 2z = 0. If the distance of L from the point (5,3,8)(5, 3, 8) is α\alpha, then 3α23\alpha^2 is equal to ........

Answer

Correct answer:158

Step-by-step solution

Standard Method

Given: The line L passes through P(2,3,1)P(2,3,1) and is parallel to the intersection of the planes x+3y2z2=0x+3y-2z-2=0 and xy+2z=0x-y+2z=0.

Find: The value of 3α23\alpha^2, where α\alpha is the distance of the point (5,3,8)(5,3,8) from L.

The direction ratios of the line parallel to the intersection of the two planes are obtained from the cross product of their normals:

i^j^k^132112=4i^4j^4k^\begin{vmatrix} \hat{i} & \hat{j} & \hat{k} \\ 1 & 3 & -2 \\ 1 & -1 & 2 \end{vmatrix} = 4\hat{i} - 4\hat{j} - 4\hat{k}

So a direction vector of L is proportional to

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

Hence the equation of the line is

x21=y31=z11\frac{x-2}{1} = \frac{y-3}{-1} = \frac{z-1}{-1}

Let Q=(5,3,8)Q=(5,3,8) and let the foot of the perpendicular from QQ to the line be RR. A general point on the line is

R(k+2,k+3,k+1)R \equiv (k+2,-k+3,-k+1)

Then the direction ratios of QRQR are

(k3,k,k7)(k-3,-k,-k-7)

Since QRLQR \perp L, their dot product with direction vector (1,1,1)(1,-1,-1) is zero:

(1)(k3)+(1)(k)+(1)(k7)=0(1)(k-3)+(-1)(-k)+(-1)(-k-7)=0 3k+4=03k+4=0 k=43k=-\frac{4}{3}

Substituting this value of kk, we get

QR=(133,43,173)QR = \left(-\frac{13}{3},\frac{4}{3},-\frac{17}{3}\right)

Therefore,

α2=(133)2+(43)2+(173)2\alpha^2 = \left(\frac{13}{3}\right)^2 + \left(\frac{4}{3}\right)^2 + \left(\frac{17}{3}\right)^2 α2=169+16+2899=4749=1583\alpha^2 = \frac{169+16+289}{9} = \frac{474}{9} = \frac{158}{3}

Hence,

3α2=1583\alpha^2 = 158

Therefore, the required answer is 158158.

Using foot of perpendicular parametrically

Given: A line through P(2,3,1)P(2,3,1) parallel to the line of intersection of two planes.

Find: 3α23\alpha^2.

The normals of the planes are n1=(1,3,2)\vec{n}_1=(1,3,-2) and n2=(1,1,2)\vec{n}_2=(1,-1,2). Their cross product gives the direction of the required line:

d=n1×n2=(4,4,4)\vec{d}=\vec{n}_1 \times \vec{n}_2 = (4,-4,-4)

So we may use

d=(1,1,1)\vec{d}=(1,-1,-1)

Distance from a point to a line in vector form

Given: Point on line P=(2,3,1)P=(2,3,1), external point Q=(5,3,8)Q=(5,3,8), and direction vector d=(1,1,1)\vec{d}=(1,-1,-1).

Find: 3α23\alpha^2.

Using the vector formula for distance from a point to a line,

α2=QP2((QP)d)2d2\alpha^2 = |Q-P|^2 - \frac{\big((Q-P)\cdot d\big)^2}{|d|^2}

Here,

QP=(3,0,7)Q-P = (3,0,7)

So,

QP2=32+02+72=58|Q-P|^2 = 3^2+0^2+7^2 = 58 (QP)d=3+07=4(Q-P)\cdot d = 3+0-7 = -4 d2=1+1+1=3|d|^2 = 1+1+1 = 3

Thus,

α2=58163=1583\alpha^2 = 58 - \frac{16}{3} = \frac{158}{3}

Hence,

3α2=1583\alpha^2 = 158

So the correct answer is 158158.

Common mistakes

  • Using the wrong direction vector for the intersection line. The line is parallel to the intersection of two planes, so its direction must be the cross product of the plane normals, not one of the normals themselves.

  • Writing the symmetric equation with an incorrect third denominator. A sign error in the direction ratios changes the entire line and gives a wrong perpendicular distance.

  • Forgetting the perpendicularity condition QRLQR \perp L. The foot of the perpendicular is not any point on the line; the dot product with the line direction must be zero.

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