Download App

STD 12 - 7.1 inderfinite integral — Mathematics STD 12 Science — Question

CBSE BoardEnglish MediumSTD 12 ScienceMathematicsSTD 12 - 7.1 inderfinite integral1 Mark
MCQ
$\int_{}^{} {\frac{{x{e^x}}}{{{{(1 + x)}^2}}}dx = } $
  • A
    $\frac{{{e^{ - x}}}}{{1 + x}} + c$
  • B
    $ - \frac{{{e^{ - x}}}}{{1 + x}} + c$
  • $\frac{{{e^x}}}{{1 + x}} + c$
  • D
    $ - \frac{{{e^x}}}{{1 + x}} + c$

Answer

Correct option: C.
$\frac{{{e^x}}}{{1 + x}} + c$
c
(c)$\int_{}^{} {\frac{{x{e^x}}}{{{{(1 + x)}^2}}}\,dx = \int_{}^{} {\frac{{(x + 1 - 1)}}{{{{(1 + x)}^2}}}{e^x}dx} } $
$ = \int_{}^{} {{e^x}\left( {\frac{1}{{1 + x}} - \frac{1}{{{{(1 + x)}^2}}}} \right)\,dx} = \frac{{{e^x}}}{{1 + x}} + c$.

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 - 7.1 inderfinite integralSTD 12 - 7.1 inderfinite integral — all question typesMathematics STD 12 Science question papersCBSE Board STD 12 Science question papersCBSE Board question paper generator

Similar questions

If ${x^2} + {y^2} = 1$ then $\left( {y' = \frac{{dy}}{{dx}},y'' = \frac{{{d^2}y}}{{d{x^2}}}} \right)$
A die is thrown three times. Getting a $3$ or a $6$ is considered success. Then the probability of at least two successes is
If $\alpha$ and $\beta$ (where $\alpha > \beta$) are two zeroes of the equation  $3\,cos{^{ - 1}}\left( {{x^2} - 5x - \frac{{11}}{2}} \right) = \pi $ then $(\alpha^2 + \beta^3)$ is -
What is the value of $ {\sin}^{-1}(\sin 160^{\circ})?$
Let $k$ and $m$ be positive real numbers such that the function $\quad f ( x )=\left\{\begin{array}{cc}3 x ^2+ k \sqrt{ x +1}, & 0< x <1 \\ mx ^2+ k ^2, & x \geq 1\end{array}\right.$ is differentiable for all $x > 0$. Then $\frac{8 f^{\prime}(8)}{f^{\prime}\left(\frac{1}{8}\right)}$ is equal to $.............$.
If $\mathrm{x}=2 \sin \theta-\sin 2 \theta$ and $\mathrm{y}=2 \cos \theta-\cos 2 \theta$ ; $\theta \in[0,2 \pi],$ then $\frac{\mathrm{d}^{2} \mathrm{y}}{\mathrm{dx}^{2}}$ at $\theta=\pi$ is :
A vector parallel to the line of intersection of the plance $\vec{\text{r}}.(3\hat{\text{i}}-\hat{\text{j}}+\hat{\text{k}})=1$ and $\vec{\text{r}}.(\hat{\text{i}}-4\hat{\text{j}}+2\hat{\text{k}})=2$ is:
If $x + y + z = 0,|x| = |y| = |z| = 2$ and $\theta $ is angle between $y$ and $z$, then the value of ${\rm{cose}}{{\rm{c}}^2}\theta + {\cot ^2}\theta $ is equal to
$\int_{}^{} {\frac{{{\rm{cosec}}\theta - \cot \theta }}{{{\rm{cosec}}\theta + \cot \theta }}} \;d\theta = $
The system of equations : $x + y + z = 5, x + 2y + 3z = 9, x + 3y + \lambda z = \mu$ has a unique solution, if