Download App

7.1 inderfinite integral — Maths STD 12 Science — Question

Gujarat BoardEnglish MediumSTD 12 ScienceMaths7.1 inderfinite integral1 Mark
MCQ
$\int_{}^{} {{{\tan }^3}} 2x\sec 2x\;dx = $
  • $\frac{1}{6}{\sec ^3}2x - \frac{1}{2}\sec 2x + c$
  • B
    $\frac{1}{6}{\sec ^3}2x + \frac{1}{2}\sec 2x + c$
  • C
    $\frac{1}{9}{\sec ^2}2x - \frac{1}{3}\sec 2x + c$
  • D
    None of these

Answer

Correct option: A.
$\frac{1}{6}{\sec ^3}2x - \frac{1}{2}\sec 2x + c$
a
(a)$\int_{}^{} {{{\tan }^3}2x\sec 2x\,dx} = \int_{}^{} {({{\sec }^2}2x - 1)\sec 2x\tan 2x\,dx} $
$\int_{}^{} {({{\sec }^3}2x\tan 2x - \sec 2x\tan 2x)dx} $
$ = \int_{}^{} {{{\sec }^3}2x\tan 2x\,dx} - \int_{}^{} {\sec 2x\tan 2x\,dx} $ ..$(i)$
Now, we take $\int_{}^{} {{{\sec }^3}2x\tan 2x\,dx} $
Put $\sec 2x = t \Rightarrow \sec 2x\tan 2x = \frac{{dt}}{2},$ then it reduces to
$\frac{1}{2}\int_{}^{} {{t^2}dt} = \frac{{{t^3}}}{6} = \frac{{{{\sec }^3}2x}}{6}$
From $(i),$ $\int_{}^{} {{{\sec }^3}2x\tan 2x\,dx} - \int_{}^{} {\sec 2x\tan 2x\,dx} $
$ = \frac{{{{\sec }^3}2x}}{6} - \frac{{\sec 2x}}{2} + c.$
Trick : Let $\sec 2x = t,$ then $\sec 2x\tan 2x\,dx = \frac{1}{2}dt$
$\frac{1}{2}\int_{}^{} {({t^2} - 1)\,dt} = \frac{1}{6}{t^3} - \frac{1}{2}t + c = \frac{1}{6}{\sec ^3}2x - \frac{1}{2}\sec 2x + c$.

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 7.1 inderfinite integral7.1 inderfinite integral — all question typesMaths STD 12 Science question papersGujarat Board STD 12 Science question papersGujarat Board question paper generator

Similar questions

$\int_0^1 {f(1 - x)\,dx} $ has the same value as the integral
Find $\mathrm{a d j}$ $\mathrm{A}$ for $\mathrm{A}=\left[\begin{array}{ll}2 & 3 \\ 1 & 4\end{array}\right]$
If $AB = C$, then matrices $A,B,C$are
If $f(x) = |x - 3|,$ then $f$ is
Let $f(x) = \mathop {\lim }\limits_{n \to \infty } \frac{{{{\left( {2\,\sin \,x} \right)}^{2n}}}}{{{3^n} - {{\left( {2\,\cos \,x} \right)}^{2n}}}};n \in Z$ ,

$x \ne m\pi  \pm \frac{\pi }{6};m \in Z$ and $f\left( {m\pi  \pm \frac{\pi }{6}} \right) = 0$ , then 

$\int \frac{d x}{x^2+2 x+5}=$ ___________ $+C$.
$\mathop {Limit}\limits_{n\,\, \to \,\,\infty } \, \frac{1}{n}\,\,\,\left[ {\,1\,\, + \,\,\sqrt {\frac{n}{{n\,\, + \,\,1}}} \,\,\, + \,\,\,\sqrt {\frac{n}{{n\,\, + \,\,2}}} \,\,\, + \,\,\,\sqrt {\frac{n}{{n\,\, + \,\,3}}} \,\,\, + \,\,\,.......\,\,\, + \,\,\,\sqrt {\frac{n}{{n\,\, + \,\,3\,\,(n\,\, - \,\,1)}}} \,} \right]$ has the value equal to
The direction cosines of any normal to the xy plane are:
  1. 1, 0 ,0
  2. 0, 1, 0
  3. 1, 1, 0
  4. 1, 1, 0
If $\text{xy}-\log_\text{e}\text{y}=1$ satisfies the equation $\text{x}(\text{yy}_2+\text{y}_1^2)-\text{y}_2+\lambda\text{yy}_1=0,$ then $\lambda=$
  1. -3
  2. 1
  3. 3
  4. None of these
In a triangle $ABC,$  right angled at the vertex $A,$  if the position vectors of $A, B$  and $C$  are respectively $3\hat i\, + \hat j\, - \hat k,\,\, - \hat i\, + 3\hat j\, + p\hat k$  and $5\hat i\, + q\hat j\, - 4\hat k,\,$ then the point $(p, q)$  lies on a line