The function, f (x) = [|x|] -|[x]| where [ x ] denotes greatest integer function

The function, f (x) = [|x|] -|[x]| where [ x ] denotes greatest i…

Let $f(x)=(1-x)^2 \sin ^2 x+x^2$ for all $x \in$ IR and let $g(x)=\int_1^x\left(\frac{2(t-1)}{t+1}-\right.$ ent $) f(t) d t$ for all $x \in(1, \infty)$.

$1.$ Which of the following is true?

$(A)$ $g$ is increasing on $(1, \infty)$

$(B)$ $g$ is decreasing on $(1, \infty)$

$(C)$ $g$ is increasing on $(1,2)$ and decreasing on $(2, \infty)$

$(D)$ $g$ is decreasing on $(1,2)$ and increasing on $(2, \infty)$

$2.$ Consider the statements :

$P$ : There exists some $x \in \operatorname{IR}$ such that $f(x)+2 x=2\left(1+x^2\right)$

$Q$ : There exists some $x \in \operatorname{IR}$ such that $2 f(x)+1=2 x(1+x)$ Then

$(A)$ both $P$ and $Q$ are true

$(B)$ $P$ is true and $Q$ is false

$(C)$ $P$ is false and $Q$ is true

$(D)$ both $P$ and $Q$ are false

Give the answer question $1$ and $2.$

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The real valued function $f(x)=\frac{\operatorname{cosec}^{-1} x}{\sqrt{x-[x]}, \text { where }}$ $[ x ]$ denotes the greatest integer less than or equal to $x,$ is defined for all $x$ belonging to

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If $\displaystyle \text{a}_{\text{ij}}=0\left (\text{i}\neq \text{j} \right )$ and $\displaystyle\text{a}_{\text{ij}}=2\left (\text{i= j} \right )$ then the matrix $\text{A}=\displaystyle \left [ \text{a}_{\text{ij}} \right ]_{\text{n}\times\text{n}}$ is a _______ matrix ?

unit
null
scalar
skew symmetric

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If $\text{x}=\text{f}(\text{t})$ and $\text{y}=\text{g}(\text{t}),$ then $\frac{\text{d}^2\text{y}}{\text{dx}^2}$ is equals to:

$\frac{\text{f}'\text{g}''-\text{g}'\text{f}''}{(\text{f}')^3}$
$\frac{\text{f}'\text{g}''-\text{g}'\text{f}''}{(\text{f}')^2}$
$\frac{\text{g}''}{\text{f}''}$
$\frac{\text{f}''\text{g}'-\text{g}''\text{f}'}{(\text{g}')^3}$

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Integration of function $\frac{x}{e^{x^2}}$ with respect to $x$ is equal to :

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Let $\hat{ i }, \hat{ j }$ and $\hat{ k }$ be the unit vectors along the three positive coordinate axes. Let

$\vec{a}=3 \hat{i}+\hat{j}-\hat{k},$

$\vec{b}=\hat{i}+b_2 \hat{j}+b_3 \hat{k}, b_2, b_3 \in R ,$

$\vec{c}=c_1 \hat{i}+c_2 \hat{j}+c_3 \hat{k}, c_1, c_2, c_3 \in R$

be three vectors such that $b_2 b_3>0, \vec{a} \cdot \vec{b}=0$ and

$\left(\begin{array}{ccc}0 & -c_3 & c_2 \\ c_3 & 0 & -c_1 \\ -c_2 & c_1 & 0\end{array}\right)\left(\begin{array}{l}1 \\ b_2 \\ b_3\end{array}\right)=\left(\begin{array}{c}3-c_1 \\ 1-c_2 \\ -1-c_3\end{array}\right)$.

Then, which of the following is/are TRUE?

$(A)$ $\overrightarrow{ a } \cdot \overrightarrow{ c }=0$

$(B)$ $\vec{b} \cdot \vec{c}=0$

$(C)$ $|\vec{b}|>\sqrt{10}$

$(D)$ $|\vec{c}| \leq \sqrt{11}$

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If the position vectors of P, Q are respectively 5a + 4b and 3a - 2b then $\vec{\text{QP}}=$

2a + 6b
2a − 6b
2a + 5b
2a − 5b

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If $y = {\sin ^{ - 1}}{{2x} \over {1 + {x^2}}} + {\sec ^{ - 1}}{{1 + {x^2}} \over {1 - {x^2}}}$, then ${{dy} \over {dx}} =$

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The integral $\int\limits_0^{\frac{1}{2}} {\frac{{\ln \,\left( {1 + 2x} \right)}}{{1 + 4{x^2}}}} dx$ , equals

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If in a binomial distribution $\text{n}=4,\text{P(X}=0)=\frac{16}{81},$ then $\text{P(X}=4)$ equals:

$\frac{1}{16}$
$\frac{1}{81}$
$\frac{1}{27}$
$\frac{1}{8}$

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