Download App

STD 12 - 3 and 4 . determinant and metrices — Mathematics STD 12 Science — Question

CBSE BoardEnglish MediumSTD 12 ScienceMathematicsSTD 12 - 3 and 4 . determinant and metrices1 Mark
MCQ
Evaluate $\left|\begin{array}{ccc}\cos \alpha \cos \beta & \cos \alpha \operatorname{csin} \beta & -\sin \alpha \\ -\sin \beta & \cos \beta & 0 \\ \sin \alpha \cos \beta & \sin \alpha \sin \beta & \cos \alpha\end{array}\right|$
  • A
    $2$
  • B
    $-1$
  • $1$
  • D
    $0$

Answer

Correct option: C.
$1$
c
$\Delta=\left|\begin{array}{ccc}\cos \alpha \cos \beta & \cos \alpha \operatorname{csin} \beta & -\sin \alpha \\ -\sin \beta & \cos \beta & 0 \\ \sin \alpha \cos \beta & \sin \alpha \sin \beta & \cos \alpha\end{array}\right|$

Expanding along $C_{3},$ we have:

$\Delta=-\sin \alpha\left(-\sin \alpha \sin ^{2} \beta+\cos ^{2} \beta \sin a\right)+\cos \alpha\left(\cos \alpha \cos ^{2} \beta+\cos \alpha \sin ^{2} \beta\right)$

$=\sin ^{2} \alpha\left(\sin ^{2} \beta+\cos ^{2} \beta\right)+\cos ^{2} \alpha\left(\cos ^{2} \beta+\sin ^{2} \beta\right)$

$=\sin ^{2} \alpha(1)+\cos ^{2} \alpha(1)$

$=1$

Need a full question paper?

Generate a complete, print-ready paper with questions like this in minutes — across 16+ boards, with answer keys.

Start Generating Free

Explore more

More "M.C.Q (1 Marks)" from STD 12 - 3 and 4 . determinant and metricesSTD 12 - 3 and 4 . determinant and metrices — all question typesMathematics STD 12 Science question papersCBSE Board STD 12 Science question papersCBSE Board question paper generator

Similar questions

If A is a non singular matrix and A' denotes the transpose of A, then
$\int\frac{\cos2\text{x}-1}{\cos2\text{x}+1}\text{ dx}=$
If $\sin (x+y) = log(x+y)$, then ${{dy} \over {dx}} =$
Let $\alpha$ and $\beta$ be the distinct roots of the equation $x^2+x-1=0$. Consider the set $T=\{1, \alpha, \beta\}$. For a $3 \times 3$ matrix $M=\left(a_{\ell}\right) 3 \times 3_3$, define $R_l=a_{l 1}+a_{l 2}+a_\beta$ and $C_j=a_{1 j}+a_{2 l}+a_{3 j}$ for $i=1,2,3$ and $j=1,2,3$

Match each entry in $List-I$ to the correct entry in $List-II$.

$List-I$ $List-II$
($P$) The number of matrices $M=\left(a_{i j}\right)_3 \times 3$ with all entries in $T$ such that $R_i=C_j=0$ for all $i, j$ is ($1$) ($1$)
($Q$) The number of symmetric matrices $M=\left(a_{i j}\right) 3 \times 3$ with all entries in $T$ such that $C_j=0$ for all $j$ is ($2$) ($2$)
($R$) Let $M=\left(a_{i j}\right) 3 \times 3$ be a skew symmetric matrix such that $a_{i j} \in T$ for $i>j$. Then the number of elements in the set $\left\{\left(\begin{array}{l}x \\ y \\ z\end{array}\right): x, y \cdot z \in R, M\left(\begin{array}{l}x \\ y \\ z\end{array}\right)=\left(\begin{array}{c}a_{12} \\ 0 \\ -a_{23}\end{array}\right)\right\}$ is is ($3$) Infinite
($S$) Let $M=\left(a_{i j}\right)_3 \times 3$ be a matrix with all entries in $T$ such that $R_i=0$ for all $i$. Then the absolute value of the determinant of $M$ is ($4$) ($6$)
  ($5$) ($0$)

The correct option is

The maximum value of $Z = 3x + 4y$ subjected to constraints $\text{x}+\text{y}\leq4,\text{x}\geq0$ and $\text{y}\geq0$ is :
Consider the binary operation * defined on Q − {1} by the rule a * b = a + b − ab for all a, b ∈ Q − {1}. The identity element in Q − {1} is:
The number of points in $(-\infty,\infty)$ for which $\text{x}^{2}-\text{x}\sin\text{x}-\cos\text{x}=0,$ is :
The projection of a line on a co-ordinate axes are $2, 3, 6$. Then the length of the line is
If a point $A ( x , y )$ lies in the region bounded by the $y$-axis, straight lines $2 y+x=6$ and $5 x-6 y=30$, then the probability that $y <1$ is
Consider a non$-$empty set consisting of children in a family and a relation $R$ defined as $\text{aRb}$ if a is brother of $b.$ Then$, R$ is: