MCQ Questions for Class 11 Engineering Physics Motion In A Plane Quiz 7

A curved section of a rod is banked for a speed $$v$$. If there is no friction between road and tyres of the car, then:

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car is more likely to slip at speeds higher than $$v$$ than speeds lower than $$v$$
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car cannot remain in static equilibrium on the curved section
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car will not slip when moving with speed $$v$$
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None of the above

A particle of mass $$M$$ is moving in a horizontal circle of radius $$R$$ with uniform speed $$v$$. When the particle moves from one point to a dramatically opposite point, its

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Momentum does not change
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Momentum changes by $$2Mv$$
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Kinetic energy changes by $$\cfrac { M{ v }^{ 2 } }{ 4 } $$
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Kinetic energy changes by $$M{ v }^{ 2 }$$

A point moves along a circle with speed $$v=at$$. The total acceleration of the point at a time when it has traced $$\dfrac{1}{8}^{th}$$ of the circumference is

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$$8a$$
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$$2a\sqrt { 4+{ \pi }^{ 2 } } $$
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$$a$$
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$$\cfrac { a }{ 2 } \sqrt { 4+{ \pi }^{ 2 } } $$

When a ceiling fan is switched off, its angular velocity fall to half while it makes $$ 36 $$ rotations . How many more rotations will be make before coming to rest ? (Assume uniform angular retardations ).

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$$ 36$$
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$$ 24 $$
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$$ 18 $$
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$$ 12 $$

A particle $$A$$ moves along a circle of radius $$R = 50\ cm$$ so that its radius vector $$r$$ relative to the point $$O$$ (figure) rotates with the constant angular velocity $$\omega = 0.40\ rad/s$$. Then magnitude of the velocity of the particle, and the magnitude of its total acceleration will be

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$$v = 0.4\ m/s, a = 0.4\ m/s^{2}$$
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$$v = 0.32\ m/s, a = 0.32\ m/s^{2}$$
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$$v = 0.32\ m/s, a = 0.4\ m/s^{2}$$
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$$v = 0.4\ m/s, a = 0.32\ m/s^{2}$$

A cricket ball is thrown over a triangle from one end of a horizontal base falls on the other end of the base after grazing the vertex. If $$\theta_1$$ and $$\theta_2$$ are the base angles of projection, then.

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$$\tan\theta_1 -\tan\theta_2 =\tan\alpha$$
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$$\sin\theta_1 +\sin\theta_2 =\sin\alpha$$
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$$\tan\theta_1 +\tan\theta_2 =\tan\alpha$$
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$$\cos\theta_1 +\cos\theta_2 =\cos \alpha$$

Consider the motion of a particle described by $$x=a\cos { t } ,y=a\sin { t } $$ and $$z=t$$. The trajectory traced by the particle as a function of time is

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Helix
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Circular
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Elliptical
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Straight line

The position vectors of A, B are a, 6 respectively. The position vector of C is $$\dfrac {5\bar{a}}{3} -\bar{b}$$. Then 3

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C is inside the $$\Delta OAB $$
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C is outside the $$\Delta OAB $$ but inside the angle OAB
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C is outside the$$\Delta OAB $$ but inside the angle OBA
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None of these

A particle is moving in a circle of radius $$r$$ with constant speed $$v$$. The change in velocity in moving from $$P$$ to $$Q$$ is

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$$2v\cos 20^{\circ}$$
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$$2v\sin 20^{\circ}$$
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$$2v\cos 40^{\circ}$$
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$$2v\sin 40^{\circ}$$

For which of the following physical quantities, it is necessary to indicate direction along with its magnitude?

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Speed
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Path length
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Displacement
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Temperature

A particle is going with constant speed along a uniform helical and spiral path separately as shown in figure then

[Assume that the vertical acceleration of the particle is negligible in case (a)]

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The velocity of the particle is constant in both cases
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The magnitude of acceleration of the particle is constant in both cases
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The magnitude of acceleration is constant in (a) and decreasing in (b)
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The magnitude of acceleration is decreasing continuously in both the cases

Two particles $$P$$ and $$Q$$ are moving on a circle. At a certain instant of time both the particles are diametrically opposite and $$P$$ has tangential acceleration $$8\ m/s^{2}$$ and centripetal centripetal $$5\ m/s^{2}$$ whereas $$Q$$ has only centripetal acceleration of $$1 m/s^{2}$$. At that instant acceleration (in $$m/s^{2})$$ of $$P$$ with respect to $$Q$$ is:

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$$14$$
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$$\sqrt {80}$$
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$$10$$
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$$12$$

A small object of mass of $$100\ gm$$ moves in a circular path. At a given instant velocity of the object is $$10\hat {i} m/s$$ and acceleration is $$(20\hat {i} + 10\hat {j})m/s^{2}$$. At this instant of time, rate of change of kinetic energy of the object is:

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$$200\ kgm^{2}/s^{3}$$
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$$300\ kgm^{2}/s^{3}$$
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$$10000\ kgm^{2}/s^{3}$$
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$$20\ kgm^{2}/s^{3}$$

A vector having magnitude $$30$$ unit makes equal angles with each of $$x,y$$ and $$z$$ axes. The component along each of $$x,y$$ and $$z$$-axis are

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$$10\sqrt {3}$$
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$$20\sqrt {3}$$
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$$30\sqrt {3}$$
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$$18\sqrt {3}$$

A particle is projected up inclined plane such that its component of velocity along the incline is 10m/s. Time of flight is 2 sec and maximum height above the incline is 5m. Then velocity of projection will be:

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$$10m/s$$
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$$10\sqrt{2}m/s$$
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$$5\sqrt{2}m/s$$
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None

A wheel is at rest. Its angular velocity increases uniformly and become 80 radians second after 5 seconds. The total angular displacement is:

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800 rad
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400 rad
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200 rad
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100 rad

A particle is projected at an angle $$\theta$$ from ground with speed $$u(g=10m/s^2)$$, then which of the following is true?

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If $$u=10m/s$$ and $$\theta = 30^o$$, then time of flight will be 1 sec
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If $$u=10\sqrt{3}m/s$$ and $$\theta=60^o$$, then time of flight will be 3 sec
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If $$u=10\sqrt{3}m/s$$ and $$\theta=60^o$$, then after 2 sec velocity becomes perpendicular to initial velocity
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If $$u=10m/s$$ and $$\theta=30^o$$, then velocity never becomes perpendicular to intial velocity during its flight

A particle is moving along a circle such that it completes one revolution in $$40$$ seconds. In $$2$$ minutes $$20$$ seconds, the ratio $$\cfrac { \left| displacement \right| }{ distance } $$ is

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$$0$$
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$$\cfrac{1}{7}$$
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$$\cfrac{2}{7}$$
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$$\cfrac{7}{11}$$

A ball is thrown horizontally with velocity $$30m/s$$ from top of a $$60m$$ high tower, simultaneously, another ball is thrown vertically upward with velocity $$40m/s$$ from the bottom of same tower. The shortest distance between the two balls is $$\left( g=10m/{ s }^{ 2 } \right) $$

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$$36m$$
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$$48m$$
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$$60m$$
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$$45m$$

A motorboat is racing towards the north at 25 $$kmh^{-1}$$ and the water current in that region is 10 $$kmh^{-1}$$ in the direction of 60$$^{\circ}$$ east of south. The resultant velocity of the boat is:

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11 $$kmh^{-1}$$
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22 $$kmh^{-1}$$
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33 $$kmh^{-1}$$
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44 $$kmh^{-1}$$

Which of the following is not a scalar quantity?

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Temperature
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Coefficient of friction
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Charge
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Impulse

A bird flies from (-3m,4m,-3m) to (7m,-2 m,-3m) in the xyz- coordinates. The bird's displacement vector is given by

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(4$$\hat{i}+2\hat{j}-6\hat{k}$$)
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$$(10\hat{i}-6\hat{j})$$
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($$\hat{i}-2\hat{j}$$)
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$$(10\hat{i}+6\hat{j}-6\hat{k})$$

Which of the following is not a property of a null vector?

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$$\vec{A}$$ + $$\vec{0}$$ = $$\vec{A}$$
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$$\lambda$$ $$\vec{0}$$ = $$\vec{0}$$ where $$\lambda$$ is a scalar
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0$$\vec{A}$$ = $$\vec{A}$$
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$$\vec{A}$$ - $$\vec{A}$$ = $$\vec{0}$$

A disc rotating about its axis, from rest it acquires a angular speed $$100rev/s$$ in $$4$$ second. The angle rotated by it during these four seconds (in radian) is

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$$100\pi$$
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$$200\pi$$
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$$300\pi$$
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$$400\pi$$

The (x,y,z) coordinates of two points A and B are given respectively as (0, 4, -2) and (-2, 8, -4). The displacement vector from A to B is:

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-2$$\hat{i}$$+4$$\hat{j}$$-2$$\hat{k}$$
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2$$\hat{i}$$-4$$\hat{j}$$+2$$\hat{k}$$
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2$$\hat{i}$$+4$$\hat{j}$$-2$$\hat{k}$$
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-2$$\hat{i}$$-4$$\hat{j}$$-2$$\hat{k}$$

The circular motion of a particle with constant speed is

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periodic and simple harmonic.
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simple harmonic but not periodic.
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neither periodic nor simple harmonic.
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periodic but not simple harmonic.

A car goes around uniform circular track of radius $$R$$ at a uniform speed $$v$$ once in every $$T$$ seconds. The magnitude of the centripetal acceleration is $$a_C$$. If the car now goes uniformly around a larger circular track of radius $$2R$$ and experiences a centripetal acceleration of magnitude $$8a_c$$, then its time period is

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$$2T$$
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$$3T$$
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$$T/2$$
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$$3/2 T$$

Which one of the following statements is true?

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A scalar quantity is the one that is conserved in a process.
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A scalar quantity is the one that can never take negative values.
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A scalar quantity is the one that does not vary from one point to another in space.
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A scalar quantity has the same value for observers with different orientations of the axes.

The equations of motion of a projectile are given by $$x = 36 \ t $$m and $$2y = 96t - 9.8 t^{2}$$ m. The angle of projection is

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sin$$^{-1}$$(4/5)
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sin$$^{-1}$$(3/5)
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sin$$^{-1}$$(4/3)
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sin$$^{-1}$$(3/4)

A projectile is thrown with an initial velocity $$(a\hat{i}+b\hat{j})ms^{-1}$$, where $$\hat{i}$$ and $$\hat{j}$$ are the unit vectors along horizontal and vertical directions respectively. If the range of projectile is twice the maximum height reached by it, then

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$$b=\frac{a}{2}$$
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$$b=a$$
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$$b = 2a$$
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$$b= 4a$$

If a body placed at the origin is acted upon by a force $$\overline{F}=(\hat{i}+\hat{j}+\sqrt2\hat{k})$$, then which of the following statements are correct?
1.Magnitude of $$\overline{F}$$ is $$(2+sqrt2)$$
2.Magnitude of $$\overline {F}$$ is 2
3. $$\overline {F}$$ makes an angle of $$45^0$$ with the Z-axis.
4. $$\overline {F}$$ makes an angle of $$30^0$$ with the Z-axis.
Select the correct answer using the codes given below.

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1 and 3
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2 and 3
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1 and 4
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2 and 4

The speed of a projectile at its maximum height is $$\dfrac{\sqrt{3}}{2}$$ times its initial speed. If the range of the projectile is P times the maximum height attained by it, then P equals

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$$4/3$$
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$$2$$ $$\sqrt{3}$$
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$$4$$ $$\sqrt{3}$$
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$$3/4$$

If a body placed at the origin is acted upon by a force $$\vec{F}$$ = $$(\hat{i} + \hat{j} + \sqrt 2 \hat{k})$$, then the following statements are correct?
Magnitude of $$\vec{F}$$ is $$(2 + \sqrt2)$$.
Magnitude of $$\vec{F}$$ is 2.
$$\vec{F}$$ makes an angle of $$45^0$$ with the Z-axis.
$$\vec{F}$$ makes an angle of $$30^0$$ with the Z-axis.
Select the correct answer using the codes given below.

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1 and 3
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2 and 3
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1 and 4
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2 and 4

A cyclist starts from centre O of a circular park of radius 1 km and moves along the path OPRQO as shown in figure. If he maintains constant speed of 10 $$ms^{-1}$$, what is his acceleration at point R ?

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10 $$ms^{-2}$$
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0.1$$ms^{-2}$$
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0.01$$ms^{-2}$$
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1$$ms^{-2}$$

A bomb is released by a horizontal flying aeroplane. The trajectory of the bomb is

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a parabola
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a straight line
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a circle
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a hyperbola

In uniform circular motion:

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both the angular velocity and the angular momentum vary
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the velocity varies but the momentum remains constant
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magnitude of both the velocity and the momentum stay constant
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the momentum varies but the velocity remains constant

A stone tied to the end of a string 100 cm long is whirled in a horizontal circle with a constant speed. If the stone makes 14 revolutions in 22 s, then the acceleration of the stone is then

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16 $$ms^{-2}$$
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4$$ms^{-2}$$
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12$$ms^{-2}$$
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8$$ms^{-2}$$

The relative velocity of $$B$$ as seen from $$A$$ is

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$$-8\sqrt { 2 } \hat { i } + 6\sqrt { 2 } \hat { j }$$
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$$4\sqrt { 2 } \hat { i } + 3\sqrt { 3 } \hat { j }$$
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$$3\sqrt { 5 } \hat { i } + 2\sqrt { 3 } \hat { j }$$
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$$3\sqrt { 2 } \hat { i } + 4\sqrt { 3 } \hat { j }$$

The minimum number of vectors having different planes which can be added to give zero resultant is

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$$2$$
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$$3$$
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$$4$$
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$$5$$

A car is moving on a circular path and takes a turn. If $${R_1}$$ and $${R_2}$$ be the reactions on the inner and outer wheels respectively, then

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$${R_1} = {R_2}$$
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$${R_1} < {R_2}$$
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$${R_1} > {R_2}$$
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$${R_1} \geqslant {R_2}$$

A cube is placed so that one corner is at the origin and three edges are along the $$x-, y-,$$ and $$z$$-axes of a coordinate system. Use vectors to compute
a. The angle between the edge along the $$z$$-axis (line ab) and the diagonal from the origin to the opposite corner (line ad).
b. The angle between line $$ac$$ (the diagonal of a face) and line $$ad$$.

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a. $$\cos^{-1}\dfrac{1}{\sqrt{2}}$$

b. $$\cos^{-1}\dfrac{\sqrt{2}}{\sqrt{3}}$$
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a. $$\cos^{-1}\dfrac{1}{\sqrt{3}}$$

b. $$\cos^{-1}\dfrac{\sqrt{2}}{\sqrt{3}}$$
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a. $$\cos^{-1}\dfrac{1}{\sqrt{3}}$$

b. $$\cos^{-1}\dfrac{\sqrt{3}}{\sqrt{3}}$$
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a. $$\cos^{-1}\dfrac{2}{\sqrt{3}}$$

b. $$\cos^{-1}\dfrac{\sqrt{2}}{\sqrt{3}}$$

The components of a vector along the $$x$$- and $$y$$-directions are $$(n +1)$$ and $$1$$, respectively. If the coordinate system is rotated by an angle $$\theta = 60^o$$, then the components change to $$n$$ and $$3$$. The value of $$n$$ is

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$$2$$
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$$\,1+ \sqrt{3} $$
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$$\,1- \sqrt{3} $$
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$$\,1\pm \sqrt{3} $$

An object moves with constant acceleration $$\vec { a }$$. Which of the following expression is/are also constant?

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$$\dfrac { d\left| \vec { v } \right| }{ dt }$$
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$$\left| \dfrac { d\vec { v } }{ dt } \right|$$
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$$\dfrac { d\left( { v }^{ 2 } \right) }{ dt }$$
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$$\dfrac { d\left( \vec { v } /\left| \vec { v } \right| \right) }{ dt }$$

A wheel is making revolutions about its axis with uniform angular acceleration. Starting from rest, it reaches 100 rev/sec in 4 seconds. Find the angular acceleration. Find the angle rotated during these four seconds.

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$$300 \pi$$ radians.
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$$400 \pi .$$ radians
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$$250 \pi $$ radians.
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$$200 \pi$$ radians.

A car moves on a circular road describing equal angles about the centre in equal intervals of time. Which of following statements about the velocity of car are not true?

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Velocity is constant
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Magnitude of velocity is constant but the direction changes
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Both magnitude and direction of velocity change
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Velocity is directed towards the center of circle

A wheel has moment of inertia $$10^{-2} kg-m^2$$ and is making 10 rps. The torque required to stop it in 5 secs is

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12.56
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9.42
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6.28
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3.14

A disc rotates through 10 radians in 4 seconds. The disc experienced uniform acceleration. If the disc starts from rest, what is the angular velocity after four seconds?

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2.5 radians/sec
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5 radians/sec
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7.5 radians/sec
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10 radians/sec

A pendulum bob of mass $$m = 80 mg$$, carrying a charge of $$q = 2 \times 10^{-8}C$$, is at rest a horizontal uniform electric field of $$E = 20,000 V/m$$. The tension $$T$$ in the thread of the pendulum and the angle $$\alpha$$ it makes with vertical is (take $$g = 9.8 m/s^2$$)

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$$\alpha \approx 27^o$$
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$$T \approx 880 \mu N$$
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$$T = 8.8 \mu N$$
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$$\alpha \approx 356o$$

A body rotates about a fixed axis with an angular acceleration of $$1$$ rad/$$sec^2$$. Through what does it rotate during the time in which its angular velocity increases from $$5$$ rad/s to $$15$$ rad/s.

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100 rad
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200 rad
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250 rad
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150 rad

The angular velocity of a wheel increases from $$100\ m/s$$ to $$300\ m/s$$ in $$10\ s$$. The revolutions made during that time is:

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$$600$$
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$$1500$$
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$$1000$$
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$$2000$$

CBSE Questions for Class 11 Engineering Physics Motion In A Plane Quiz 7 - MCQExams.com

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Practice Class 11 Engineering Physics Quiz Questions and Answers

CBSE Questions for Class 11 Engineering Physics Motion In A Plane Quiz 7 - MCQExams.com

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Practice Class 11 Engineering Physics Quiz Questions and Answers

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