2 (e^ x +e^ -x )^2 dx= 1. -e^ -x e^ x +e^ -x +C 2. -1 e^ x +e^ -x +C 3. -1 (e^ x +1)^2 +C 4. 1 e^ x -e^ -x +C

1. -e^ -x e^ x +e^ -x +C Solution: I= 2 (e^ x +e^ -x )^2 dx I= 2e^ 2x (e^ 2x +1)^2 dx Put t=e^ 2x +1 dt=2e^ 2x dx I= dt t^2 I=-1 t +C I=-1 e^ 2x +1 +C I= -1 e^ x e^ x +e^ -x +C I= -e^ -x e^ x +e^ -x +C

2 (e^ x +e^ -x )^2 dx= 1. -e^ -x e^ x +e^ -x +C 2. -1 e^ x +e^ -x…

If ${u^2} = {(x - a)^2} + {(y - b)^2} + {(z - c)^2}$, then $\sum {{{\partial ^2}u} \over {\partial {x^2}}} = $

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Integral curve satisfying $y' = \frac{{{x^2} + {y^2}}}{{{x^2} - {y^2}}},\;y(1) = 2$ has the slope at the point $(1, 0)$ of the curve, equal to

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Let $f(x) = sin\,x,\,\,g(x) = x.$

Statement $1:$ $f(x)\, \le \,g\,(x)$ for $x$ in $(0,\infty )$

Statement $2:$ $f(x)\, \le \,1$ for $(x)$ in $(0,\infty )$ but $g(x)\,\to \infty$ as $x\,\to \infty$

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The integral $\int {\frac{{xdx}}{{2 - {x^2} + \sqrt {2 - {x^2}} }}} $ equals

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The ratio of the areas between the curves $\text{y}=\cos\text{x}$ and $\text{y}=\cos2\text{x}$ and x-axis from x = 0 to x = 0 to $\text{x}=\frac{\pi}{3}$

$1:2$
$2:1$
$\sqrt{3}:1$
none of these

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If $f(x)=\sqrt{1+\cos ^2\left(x^2\right)}$, then the value of $f^{\prime}\left(\frac{\sqrt{\pi}}{2}\right)$ is

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$\int_{\, - 1}^{\,2} {|x|\,dx} =$

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If the range of $f(x) = \frac{2x^2-14x^2-8x+49}{x^4-7x^2-4x+23}$ is ($a, b$], then ($a +b$) is

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If $\text{y}=\log\Big(\frac{1-\text{x}^2}{1+\text{x}^2}\Big),$ then $\frac{\text{dy}}{\text{dx}}=$

$\frac{4\text{x}^3}{1-\text{x}^4}$
$-\frac{4\text{x}}{1-\text{x}^4}$
$\frac{1}{4-\text{x}^4}$
$-\frac{4\text{x}^3}{1-\text{x}^4}$

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Let $a_1, a_2, a_3, \ldots \ldots$ be an A.P. If $a_7=3$, the product $a_1 a_4$ is minimum and the sum of its first $n$ terms is zero, then $n !-4 a_{n(n+2)}$ is equal to :

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INTEGRALS — Maths STD 12 Science — Question

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