MCQ Questions for Class 12 Commerce Maths Application Of Derivatives Quiz 11

The number of points on the curve $$x^{3/2}+y^{3/2}=a^{3/2}$$, where the tangents are equally inclined to the axes, is

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$$2$$
0%
$$1$$
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$$0$$
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$$4$$

Let $$\displaystyle f(x) = ln \: mx (m > 0)$$ and $$g(x) = px$$. Then the equation $$\displaystyle |f(x)| = g(x)$$ has only one solution for

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$$\displaystyle 0 < p < \frac {m}{e}$$
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$$\displaystyle p < \frac {e}{m}$$
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$$\displaystyle 0 < p < \frac {e}{m}$$
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$$\displaystyle p > \frac {m}{e}$$

Let the equation of a curve be $$x=a\left ( \theta +\sin \theta \right )$$, $$y=a\left ( 1-\cos \theta \right )$$. If $$\theta $$ changes at a constant rate $$k$$ then the rate of change of slope of the tangent to the curve at $$\displaystyle \theta =\frac{\pi }{2}$$ is

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$$\displaystyle \frac{2k}{\sqrt{3}}$$
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$$\displaystyle \frac{k}{\sqrt{3}}$$
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$$k$$
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none of these

The real number $$\displaystyle '\alpha'$$ such that the curve $$\displaystyle f(x) = e^x$$ is tangent to the curve $$\displaystyle g(x) = \alpha x^2$$.

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$$\displaystyle \frac{e^2}{4}$$
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$$\displaystyle \frac{e^2}{2}$$
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$$\displaystyle \frac{e}{4}$$
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$$\displaystyle \frac{e}{2}$$

The area of a triangle is computed using the formula $$S=\dfrac {1}{2}$$ bc sin A. If the relative errors made in measuring b, c and calculating S are respectively $$0.02$$, $$0.01$$ and $$0.13$$ the approximate error in A when $$A=\pi /6$$ is

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$$0.05$$ radians
0%
$$0.01$$ radians
0%
$$0.05$$ degree
0%
$$0.01$$ degree

If the circle $$x^2+y^2+2gx+2fy+c=0$$ is touched by $$y=x$$ at P such that OP = $$6\sqrt{2}$$
then the value of c is

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36
0%
144
0%
72
0%
None of these

The angle made by the tangent of the curve $$\displaystyle x = a(t + \sin t \cos t); y = a (1 + \sin t)^2$$ with the x-axis at any point on it is

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$$\displaystyle \frac {1}{4} (\pi + 2t)$$
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$$\displaystyle \frac {1 - \sin t}{ \cos t}$$
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$$\displaystyle \frac {1}{4} (2t - \pi)$$
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$$\displaystyle \frac {1 + \sin t}{\cos 2 t}$$

Let $$\displaystyle \:f : R\rightarrow R$$ be a function such that $$\displaystyle \:f \left ( x \right )= ax+3\sin x+4\cos x.$$ Then $$\displaystyle \:f \left ( x \right )$$ is invertible if

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$$\displaystyle \:a \epsilon \left ( -5, 5 \right )$$
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$$\displaystyle \:a \epsilon \left ( -\infty , 5 \right )$$
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$$\displaystyle \:a \epsilon \left ( -5, +\infty \right )$$
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none of these

For the curve represented parametrically by the equations, $$\displaystyle x = \displaystyle\frac{2}{cot\:t} + 1$$ & $$\displaystyle y = tan \: t + cot \: t$$

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tangent at $$\displaystyle t = \displaystyle\frac{\pi}{4}$$ is parallel to x - axis
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normal at $$\displaystyle t =\displaystyle\frac{\pi}{4}$$ is parallel to y - axis
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tangent at $$\displaystyle t =\displaystyle\frac{\pi}{4}$$ is parallel to the line $$y = x$$
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tangent and normal intersect at the point $$(2, 1)$$

Consider the curve represented parametrically by the equation
$$\displaystyle x = t^3 - 4t^2 - 3t$$ and $$\displaystyle y = 2t^2 + 3t - 5$$ where $$\displaystyle t \: \epsilon \: R$$.
If $$H$$ denotes the number of point on the curve where the tangent is horizontal and $$V$$ the number of point where the tangent is vertical then

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$$H = 2$$ and $$V = 1$$
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$$H = 1$$ and $$V = 2$$
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$$H = 2$$ and $$V = 2$$
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$$H = 1$$ and $$V = 1$$

If the line $$ax+by+c=0$$ is a normal to the rectangular hyperbola $$xy=1$$ then

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$$a>0, b>0$$
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$$a>0, b<0$$
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$$a<0, b>0$$
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$$a<0, b<0$$

The point (s) on the curve $$\displaystyle y^{3}+3x^{2}= 12y,$$ where the tangent is vertical (i.e., parallel to the y-axis), is / true

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$$\displaystyle \left ( \pm \frac{4}{\sqrt{3}},-2 \right )$$
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$$\displaystyle \left ( \pm \frac{\sqrt{11}}{3},1 \right )$$
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$$\displaystyle \left ( 0, 0 \right )$$
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$$\displaystyle \left ( \pm \frac{4}{\sqrt{3}},2 \right )$$

For a $$\displaystyle a\epsilon \left [ \pi , 2\pi \right ],$$ the function $$\displaystyle f\left ( x \right )= \frac{1}{3}\sin a \tan ^{3}x+\left ( \sin a-1 \right )\tan x+ \frac{\sqrt{a-2}}{\sqrt{8-a}}$$

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$$\displaystyle x= n\pi \left ( n\epsilon I \right )$$ as critical points
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no critical points
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$$\displaystyle x= 2n\pi \left ( n\epsilon I \right )$$ as critical points
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$$\displaystyle x= \left ( 2n+1 \right )\pi \left ( n\epsilon I \right )$$ as critical points.

The point(s) on the curve $$y^{3}+3x^{2}=12y$$ the tangent is vertical is (are)

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$$\left ( \pm 4/\sqrt{3}\: -2 \right )$$
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$$\left ( \pm \sqrt{11/3},1 \right )$$
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$$\left ( 0,0 \right )$$
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$$\left ( \pm 4/\sqrt{3}\: ,2 \right )$$

The set of values of $$\displaystyle \lambda $$ for which the function $$\displaystyle f\left ( x \right )= \left ( 4\lambda -3 \right )\left ( x+\log 5 \right )+2\left ( \lambda -7 \right ). \cot \dfrac{x}{2}\sin ^{2}\dfrac{x}{2}.$$ does not posses critical point is:

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$$\displaystyle \left ( 1,\infty \right )$$
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$$\displaystyle \left ( 2,\infty \right )$$
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$$\displaystyle \left ( -\infty ,-4/3 \right )$$
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$$\displaystyle \left ( -\infty ,-1 \right )$$

Explanation

The positive value of $$k$$ for which $$ke^x-x=0$$ has only one real solution is

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$$\dfrac{1}{e}$$
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1
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e
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$$\log_{e}2$$

The coordinates of the point $$P$$ on the curve $$y^{2}= 2x^{3}$$ the tangent at which is perpendicular to the line $$4x-3y + 2 = 0$$, are given by

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$$\left ( 2,4 \right )$$
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$$\left ( 1,\sqrt{2} \right )$$
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$$\left ( 1/2,-1/2 \right )$$
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$$\left ( 1/8,-1/16 \right )$$

Find the co-ordinates of the point (s) on the curve $$\displaystyle y= \frac{x^{2}-1}{x^{2}+1}, x> 0$$ such that tangent at these point (s)have the greatest slope.

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$$\displaystyle \left ( \frac{1}{\sqrt{3}},-\frac{1}{\sqrt{2}} \right ).$$
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$$\displaystyle \left ( \frac{1}{\sqrt{3}},-\frac{1}{{2}} \right ).$$
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$$\displaystyle \left ( \frac{1}{{3}},-\frac{4}{{5}} \right ).$$
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$$\displaystyle \left ( {\sqrt{3}},\frac{1}{{2}} \right ).$$

The equation of the tangents to $$\displaystyle 4x^{2}-9y^{2}=36$$ which are perpendicular to the straight line $$\displaystyle 2y+5x= 10$$ are

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$$\displaystyle 5\left ( y-3 \right )=2 \left ( x-\sqrt{\frac{117}{4}} \right )$$
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$$\displaystyle 5\left ( y-2 \right )=2 \left ( x-\sqrt{-18} \right )$$
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$$\displaystyle 5\left ( y+2 \right )=2 \left ( x-\sqrt{-18} \right )$$
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none of these

For the curve $${x}^{2}+4xy+8{y}^{2}=64$$ the tangents are parallel to the $$x$$-axis only at the points

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$$(0,2\sqrt { 2 } )$$ and $$(0,-2\sqrt { 2 } )$$
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$$(8,-4)$$ and $$(-8,4)$$
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$$(8\sqrt { 2 } ,-2\sqrt { 2 } )$$ and $$(-8\sqrt { 2 } ,2\sqrt { 2 } )$$
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$$(9,0)$$ and $$(-8,0)$$

Given function $$f(x)=\left(\displaystyle\frac{e^{2x}-1}{e^{2x}+1}\right)$$ is.

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Increasing
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Decreasing
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Even
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None of these

If the line $$ax + by + c = 0$$ is a normal to the curve $$xy = 1$$. Then

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$$a> 0, b> 0$$
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$$a> 0, b < 0$$
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$$a < 0, b > 0$$
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$$a < 0, b < 0$$

The coordinates of the points(s) at which the tangents to the curve $$\displaystyle y=x^{3}-3x^{2}-7x+6$$ cut the positive semi axis OX a line segment half that on the negative semi axis OY is/are given by

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$$(-1, 9)$$
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$$(3, -15)$$
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$$(1, -3)$$
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none

The tangent to the curve $$x= a\sqrt{\cos 2\theta }\cos \theta $$, $$y= a\sqrt{\cos 2\theta }\sin \theta
$$ at the point corresponding to $$\theta = \pi /6$$ is

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parallel to the $$x$$-axis
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parallel to the $$y$$-axis
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parallel to line $$y = x$$
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none of these

The tangent to the curve $$y=e^{x}$$ drawn at the point $$\left ( c,e^{c} \right )$$ intersects the line joining the points $$(c -1,e^{c-1})$$ and $$(c +1,e^{c+1}) $$

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on the left of $$x = c$$
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on the right of $$x = c$$
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at no paint
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at all points

If $$f(x)=e^x(x-2)^2$$ then

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f is increasing in $$(-\infty, 0)$$ and $$(2, \infty)$$ deceasing in $$(0, 2)$$
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f is increasing in $$(-\infty, 0)$$ and deceasing in $$(0, \infty)$$
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f is increasing in $$(2, \infty)$$ and deceasing in $$(-\infty, 0)$$
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f is increasing in $$(0, 2)$$ and deceasing in $$(-\infty, 0)$$ and $$(2, \infty)$$

The value of $$a$$ for which the function $$f(x)=(4a-3)(x+\log 5)+2(a-7)\cot \dfrac x2\sin ^2\dfrac x2$$ does not possess critical points is

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$$(-\infty,-\dfrac 43)$$
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$$(-\infty,-1)$$
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$$[1,\infty)$$
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$$(2,\infty)$$

All the critical points of $$f(x)=\dfrac {|2-x|}{x^2}$$ is/are:

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$$x=0,2$$
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$$x=2,4$$
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$$x=2,-4$$
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None of the above.

If the slope of the curve $$y=\cfrac { ax }{ b-x } $$ at the point $$(1,1)$$ is $$2$$, then the values of $$a$$ and $$b$$ are respectively

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$$1,-2$$
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$$-1,2$$
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$$1,2$$
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None of these

If $$f:[1, 10]\rightarrow[1,10]$$ is a non-decreasing function and $$g:[1,10] \rightarrow [1,10]$$ is a non-increasing function, Let $$h(x) = f(g(x))$$ with $$h(1)=1$$. then, $$h(2)$$

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less than $$1$$
0%
is more than two
0%
is equal to $$2$$
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is not defined

If $$y = 4x - 5$$ is a tangent to the curve $$y^{2} = px^{3} + q$$ at $$(2, 3)$$, then

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$$p = 2, q = -7$$
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$$p = -2, q = 7$$
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$$p = -2, q = -7$$
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$$p = 2, q = 7$$

The curve given by $$x+y={ e }^{ xy }$$ has a tangent parallel to the y-axis at the point

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$$(0,1)$$
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$$(1,0)$$
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$$(1,1)$$
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$$(-1,-1)$$

Abscissa of $$p_{1}, p_{2}, p_{3} .... p_{n}$$ are in

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A.P.
0%
G.P.
0%
H.P
0%
None

If $$g(x)$$ is continuous function at $$x = a$$, such that $$g(a) > 0$$ and $$f'(x) (g(x))(x^{2} - ax + a^{2}) \forall x\epsilon R$$, then $$f(x)$$ is

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Increasing in the neighbourhood of $$x = a$$
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Decreasing in the neighbourhood of $$x = a$$
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Constant in the neighbourhood of $$x = a$$
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Maximum at $$x = a$$

Let $$f'(\sin { x } )<0$$ and $$f''(\sin { x } )>0>\forall x\in \left( 0,\cfrac { \pi }{ 2 } \right) $$ and $$g(x)=f'(\sin { x } )+f'(\cos { x } ) $$, then $$g(x)$$ is decreasing in

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$$\left( \cfrac { \pi }{ 4 } ,\cfrac { \pi }{ 2 } \right) $$
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$$\left( 0,\cfrac { \pi }{ 4 } \right) $$
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$$\left( 0,\cfrac { \pi }{ 2 } \right) $$
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$$\left( \cfrac { \pi }{ 6 } ,\cfrac { \pi }{ 2 } \right) $$

$$f(x)=e^{3x}-sinx+x^{2}$$, Find $$f '(x)$$

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$$3e^{3x}-cosx+2x$$
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$$e^{3x}+cosx+2x$$
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$$3e^{3x}+cosx+x$$
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$$3e^{3x}+sinx+2x$$

Given that f(x) is a differentiable function of x and that $$f(x).f(y)=f(x)-4-f(y)+f(xy)-2$$ and that $$f(2)=5$$. Then $$f'(3)$$ is equal to

0%
2
0%
24
0%
15
0%
19

The curve that passes through the point $$(2,3)$$ and has the property that the segment of any tangent to it lying between the coordinate axes is bisected by the point of contact, is given by

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$${ \left( \cfrac { x }{ 2 } \right) }^{ 2 }+{ \left( \cfrac { y }{ 3 } \right) }^{ 2 }=2\quad $$
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$$2y-3x=0$$
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$$y=\cfrac { 6 }{ x } $$
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$${ x }^{ 2 }+{ y }^{ 2 }=13$$

If the line $$y=4x-5$$ touches to the curve $${ y }^{ 2 }=a{ x }^{ 3 }+b$$ at the point $$(2,3)$$ then $$7a+2b=$$

0%
$$0$$
0%
$$1$$
0%
$$-1$$
0%
$$2$$

If $$f(x)$$ is an even function, where $$f(x)\ne 0$$, then which one of the following is correct?

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$$f'(x)$$ is an even function
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$$f'(x)$$ is an odd function
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$$f'(x)$$ may be an even or odd function depending on the type of function
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$$f'(x)$$ is a constant function

For the curve $$x=t^2-1$$, $$y=t^2-t$$, the tangent is perpendicular to $$x$$-axis then

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$$t=0$$
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$$t=\dfrac{1}{2}$$
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$$t=1$$
0%
$$t=\dfrac{1}{\sqrt{3}}$$

Let $$f\left( x \right) = {\tan ^{ - 1}}x - \frac{{In\left| x \right|}}{2},x \ne 0.$$. Then $$f\left( x \right)$$ is increasing in

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$$\left( {0,\infty } \right)$$
0%
$$\left( { - \infty ,0} \right)$$
0%
$$\left( {1,\infty } \right)$$
0%
none of these

If the tangent at $$({x_1},{y_1})$$ to the curve $${x^3} + {y^3} = {a^3}$$ meets the curve again at $$({x_2},{y_2})$$, then

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$${{{x_2}} \over {{x_1}}} + {{{y_2}} \over {{y_1}}} = - 1$$
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$${{{x_2}} \over {{y_1}}} + {{{x_1}} \over {{y_2}}} = - 1$$
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$${{{x_1}} \over {{x_2}}} + {{{y_1}} \over {{y_2}}} = - 1$$
0%
$${{{x_2}} \over {{x_1}}} + {{{y_2}} \over {{y_1}}} = 1$$

If the error committed in measuring the radius of the circle is $$0.05\%$$, then the corresponding error in calculating the area is:

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$$0.05\%$$
0%
$$0.025\%$$
0%
$$0.25\%$$
0%
$$0.1\%$$

A point on the curve $$y = 2{x^3} + 13{x^2} + 5x + 9$$, the tangent at which passes through the origin is

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$$(1, 15)$$
0%
$$(1, -15)$$
0%
$$(15, 1)$$
0%
$$(-1, 15)$$

The value of n for which the length of the sub-normal at any point of the curve $$y^3= a^{1-n}x^{2n}$$ must be constant, is

0%
$$-1$$
0%
$$-\frac{1}{2}$$
0%
$$\frac{3}{4}$$
0%
$$1$$

The value of 'a' for which the function $$f\left( x \right) = \left( {a + 2} \right){x^3} - 3a{x^2} + 9ax - 1$$ decreases for all real values of x is

0%
$$( - \infty , - 3]$$
0%
$$\left( { - \infty , - 3} \right)$$
0%
$$\left( { - \infty , - 2} \right)$$
0%
$$( - \infty , - 3] \cup [0,\infty )$$

If the tangent at any point on the curve $$x^{4} +y^{4}=a^{4}$$ cuts off intercepts $$p$$ and $$q$$ on the coordinate axes the value of $$p^{-4/3}+q^{-4/3}$$ is

0%
$$a^{-4/3}$$
0%
$$a^{-1/3}$$
0%
$$a^{1/2}$$
0%
$$None\ of\ these$$

The slope of the tangent to the curve at a point $$(x,y) $$ on it is proportional to $$(x-2).$$ If the slope of the tangent to the curve at $$(10,-9)$$ on it is $$-3$$. The equation of the curves is .

0%
$$y=k(x-2)^2$$
0%
$$y=\dfrac{-3}{16}(x-2)^2+1$$
0%
$$y=\dfrac{-3}{16}(x-2)^2+3$$
0%
$$y=K(x+2)^2$$

At any two points of the curve represented parametrically by $$x = a\left( {2\cos t - \cos 2t} \right);y = a\left( {2\sin t - \sin 2t} \right)$$ the tangent are parallel to the axis of $$x$$ corresponding to the values of the parameter $$1$$ differing from each other by

0%
$$\frac{{2\pi }}{3}$$
0%
$$\frac{{3\pi }}{4}$$
0%
$$\frac{\pi }{2}$$
0%
$$\frac{\pi }{3}$$

CBSE Questions for Class 12 Commerce Maths Application Of Derivatives Quiz 11 - MCQExams.com

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Practice Class 12 Commerce Maths Quiz Questions and Answers

CBSE Questions for Class 12 Commerce Maths Application Of Derivatives Quiz 11 - MCQExams.com

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Practice Class 12 Commerce Maths Quiz Questions and Answers

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