Download App

STD 12 - 7.1 inderfinite integral — JEE STD 11 Science — Question

Gujarat BoardEnglish MediumSTD 11 ScienceJEESTD 12 - 7.1 inderfinite integral4 Marks
MCQ
$\int_{}^{} {\log x(\log x + 2)\;dx = } $
  • $x{(\log x)^2} + c$
  • B
    $x{(1 + \log x)^2} + c$
  • C
    $x[1 + {(\log x)^2}] + c$
  • D
    None of these

Answer

Correct option: A.
$x{(\log x)^2} + c$
a
(a) $I = \int_{}^{} {\log x(\log x + 2)\,dx} $
Put $\log x = t \Rightarrow {e^t} = x \Rightarrow {e^t}dt = dx,$ then
$I = \int_{}^{} {t(t + 2){e^t}dt} = {t^2}.\,{e^t} + c = x{(\log x)^2} + c.$

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

JEE STD 11 Science question papersGujarat Board STD 11 Science question papersGujarat Board question paper generator

Similar questions

Let $A _{1}, A _{2}, A _{3}, \ldots \ldots$ be an increasing geometric progression of positive real numbers. If $A _{1} A _{3} A _{5} A _{7}=\frac{1}{1296}$ and $A _{2}+ A _{4}=\frac{7}{36}$, then, the value of $A _{6}+ A _{8}+ A _{10}$ is equal to
Let $A =\left(\begin{array}{ll}2 & -2 \\ 1 & -1\end{array}\right)$ and $B =\left(\begin{array}{ll}-1 & 2 \\ -1 & 2\end{array}\right)$. Then the number of elements in the set $\left\{( n , m ): n , m \in\{1,2, \ldots . .10\}\right.$ and $\left.nA ^{ n }+ mB ^{ m }= I \right\}$ is
A vector which bisects the angle between $a =3 i -4 k$ and $b =5 j +12 k$ is
In the four numbers first three are in $G.P.$ and last three are in $A.P.$ whose common difference is $6$. If the first and last numbers are same, then first will be
The co-ordinates of the point in which the line joining the points $(3,\,\;5,\; - 7)$ and $( - 2,\,\;1,\,\;8)$ is intersected by the plane $yz$ are given by
Let $a$ and $b$ be positive real numbers such that $a > 1$ and $b < a$. Let $P$ be a point in the first quadrant that lies on the hyperbola $\frac{ x ^2}{ a ^2}-\frac{ y ^2}{ b ^2}=1$. Suppose the tangent to the hyperbola at $P$ passes through the point $(1,0)$, and suppose the normal to the hyperbola at $P$ cuts off equal intercepts on the coordinate axes. Let $\Delta$ denote the area of the triangle formed by the tangent at $P$, the normal at $P$ and the $x$-axis. If $e$ denotes the eccentricity of the hyperbola, then which of the following statements is/are $TRUE$?

$(A)$ $1 < e < \sqrt{2}$

$(B)$ $\sqrt{2} < e < 2$

$(C)$ $\Delta=a^4$

$(D)$ $\Delta=b^4$

The points $A(a, 0), B(0, b), C(c, 0) \,\,\&\,\, D(0, d)$ are such that $ac = bd\, \,\,\&\,\, \,a, b, c, d$ are all non-zero. The the points :
If the system of equations $x + y+  z = 5$ ; $x + 2y + 3z = 9$ ; $x + 3y + \alpha z = \beta $ has infinitely many solutions, then $\beta  - \alpha $ equals
In a study about a pandemic, data of $900$ persons was collected. It was found that

$190$ persons had symptom of fever,

$220$ persons had symptom of cough,

$220$ persons had symptom of breathing problem,

$330$ persons had symptom of fever or cough or both,

$350$ persons had symptom of cough or breathing problem or both,

$340$ persons had symptom of fever or breathing problem or both,

$30$ persons had all three symptoms (fever, cough and breathing problem).

If a person is chosen randomly from these 900 persons, then the probability that the person has at most one symptom is. . . . .

If $x$ denotes the number of sixes in four consecutive throws of a dice, then $P\,(x = 4)$ is