MCQMediumJEE 2023Cross Product

JEE Mathematics 2023 Question with Solution

Let SS be the set of all (λ,μ)(\lambda,\mu) for which the vectors

λij+k,i+2j+μk,and3i4j+5k\lambda \mathbf{i}-\mathbf{j}+\mathbf{k},\quad \mathbf{i}+2\mathbf{j}+\mu\mathbf{k}, \quad \text{and} \quad 3\mathbf{i}-4\mathbf{j}+5\mathbf{k}

where λμ=5\lambda-\mu=5, are coplanar. Then

(λ,μ)S80(λ2+μ2)\sum_{(\lambda,\mu)\in S} 80(\lambda^2+\mu^2)

is equal to

  • A

    21302130

  • B

    22102210

  • C

    22902290

  • D

    23702370

Answer

Correct answer:C

Step-by-step solution

Standard Method

Given: The vectors are

λij+k,i+2j+μk,3i4j+5k\lambda \mathbf{i}-\mathbf{j}+\mathbf{k},\quad \mathbf{i}+2\mathbf{j}+\mu\mathbf{k},\quad 3\mathbf{i}-4\mathbf{j}+5\mathbf{k}

with λμ=5\lambda-\mu=5.

Find:

(λ,μ)S80(λ2+μ2)\sum_{(\lambda,\mu)\in S} 80(\lambda^2+\mu^2)

when the vectors are coplanar.

For coplanarity, the scalar triple product must be zero:

λ1112μ345=0\begin{vmatrix} \lambda & -1 & 1 \\ 1 & 2 & \mu \\ 3 & -4 & 5 \end{vmatrix}=0

Evaluating the determinant,

λ2μ45+11μ35+11234=0\lambda \begin{vmatrix} 2 & \mu \\ -4 & 5 \end{vmatrix} +1 \begin{vmatrix} 1 & \mu \\ 3 & 5 \end{vmatrix} +1 \begin{vmatrix} 1 & 2 \\ 3 & -4 \end{vmatrix}=0 λ(10+4μ)+(53μ)+(46)=0\lambda(10+4\mu)+(5-3\mu)+(-4-6)=0 λ(10+4μ)3μ5=0\lambda(10+4\mu)-3\mu-5=0

Using the given relation,

λ=μ+5\lambda=\mu+5

Substitute into the equation:

(μ+5)(10+4μ)3μ5=0(\mu+5)(10+4\mu)-3\mu-5=0 4μ2+27μ+45=04\mu^2+27\mu+45=0

Now solve:

μ=27±27244458=27±38\mu=\frac{-27\pm\sqrt{27^2-4\cdot4\cdot45}}{8}=\frac{-27\pm3}{8}

Hence,

μ=3,154\mu=-3,\quad -\frac{15}{4}

Corresponding values of λ\lambda are

λ=2,54\lambda=2,\quad \frac{5}{4}

So the pairs are (2,3)(2,-3) and (54,154)\left(\frac{5}{4},-\frac{15}{4}\right).

For (2,3)(2,-3):

λ2+μ2=4+9=13\lambda^2+\mu^2=4+9=13 80×13=104080\times13=1040

For (54,154)\left(\frac{5}{4},-\frac{15}{4}\right):

λ2+μ2=2516+22516=25016\lambda^2+\mu^2=\frac{25}{16}+\frac{225}{16}=\frac{250}{16} 80×25016=125080\times\frac{250}{16}=1250

Therefore,

(λ,μ)S80(λ2+μ2)=1040+1250=2290\sum_{(\lambda,\mu)\in S}80(\lambda^2+\mu^2)=1040+1250=2290

So, the correct option is C.

Use the relation first

Given: The vectors are coplanar and satisfy λμ=5\lambda-\mu=5.

Find: The required sum.

A quick way is to use λ=μ+5\lambda=\mu+5 immediately in the scalar triple product condition. Since coplanarity means determinant zero,

μ+51112μ345=0\begin{vmatrix} \mu+5 & -1 & 1 \\ 1 & 2 & \mu \\ 3 & -4 & 5 \end{vmatrix}=0

This reduces the problem to one variable directly and gives

4μ2+27μ+45=04\mu^2+27\mu+45=0

So,

μ=3,154\mu=-3,\quad -\frac{15}{4}

and hence

λ=2,54\lambda=2,\quad \frac{5}{4}

Now compute the two values of 80(λ2+μ2)80(\lambda^2+\mu^2):

80(22+(3)2)=104080(2^2+(-3)^2)=1040 80((54)2+(154)2)=125080\left(\left(\frac{5}{4}\right)^2+\left(-\frac{15}{4}\right)^2\right)=1250

Adding,

1040+1250=22901040+1250=2290

Therefore, the correct option is C.

This works faster because the linear relation removes one variable before expanding everything.

Common mistakes

  • Using dot product instead of scalar triple product for coplanarity is incorrect because dot product tests perpendicularity of two vectors, not coplanarity of three vectors. Set the determinant of the three vectors equal to zero instead.

  • Making a sign error while expanding the determinant gives a wrong quadratic in μ\mu. Track the cofactors carefully, especially the terms involving 1-1 and the constant term from 1234\begin{vmatrix} 1 & 2 \\ 3 & -4 \end{vmatrix}.

  • Forgetting to use the relation λμ=5\lambda-\mu=5 after obtaining the coplanarity equation leaves two variables and makes the problem incomplete. Substitute λ=μ+5\lambda=\mu+5 to reduce it to one quadratic equation.

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