$\text { and } x \in[0,3]$
$g ^{\prime}( x )=\frac{1}{\sqrt{1+x^2}}$
Now, $0 \leq x \leq 3$
$0 \leq x^2 \leq 9$
$1 \leq 1+x^2 \leq 10$
So, $\quad 2+\frac{1}{10} \leq f^{\prime}(x) \leq 3$
$\frac{21}{10} \leq f^{\prime}(x) \leq 3$ and $\frac{1}{\sqrt{10}} \leq g^{\prime}(x) \leq 1$ option $(4)$ is incorrect
From above, $g ^{\prime}( x )< f ^{\prime}( x ) \forall x \in[0,3]$ Option $(1)$ is incorrect. $f ^{\prime}( x ) \& g ^{\prime}( x )$ both positive so $f ( x ) \& g ( x )$ both are increasing
So, $\quad \max \left( f ( x )\right.$ at $x =3$ is $6+\tan ^{-1} 3$
$\operatorname{Max}(g(x)$ at $x=3$ is $\ln (3+\sqrt{10})$
And $6+\tan ^{-1} 3 > \ln (3+\sqrt{10})$
Option $(2)$ is correct
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where $[.]$ & $\{.\}$ denotes greatest integer function and fractional part function respectively.
If the volume of the parallelopiped, whose adjacent sides are represented by the vectors $\overrightarrow{ u }, \overrightarrow{ v }$ and $\overrightarrow{ w }$ , is $\sqrt{2}$, then the value of $|3 \vec{u}+5 \vec{v}|$ is. . . . .
$x-2 y=1, x-y+k z=-2, k y+4 z=6, k \in R$
consider the following statements :
$(A)$ The system has unique solution if $k \neq 2$, $k \neq-2$
$(B)$ The system has unique solution if $k =-2$.
$(C)$ The system has unique solution if $k =2$.
$(D)$ The system has no-solution if $k =2$.
$(E)$ The system has infinite number of solutions if $k \neq-2$
Which of the following statements are correct?
$f(x)=\frac{\cos ^{-1}\left(\frac{x^{2}-5 x+6}{x^{2}-9}\right)}{\log _{e}\left(x^{2}-3 x+2\right)} \text { is }$