MCQ Questions for Class 11 Engineering Physics Oscillations Quiz 16

The total spring constant of the system as shown in the figure will be:

0%
$$\dfrac{k_1}{2} + k_2$$
0%
$${[\dfrac{1}{2k_1}+\dfrac{1}{k_2}]}^{-1}$$
0%
$$\dfrac{1}{2k_1} + \dfrac{1}{k_2}$$
0%
$${[\dfrac{2}{k_1}+\dfrac{1}{k_2}]}^{-1}$$

A particles moves on the x-axis according to the equation $${ x=x }_{ 0 }{ sin }^{ 2 }\omega t$$. The motion is simple harmonic

0%
With amplitude $${ x }_{ 0 }$$
0%
With amplitude $${ 2x }_{ 0 }$$
0%
With time period $$\dfrac { 2\pi }{ \omega } $$
0%
With time period $$\dfrac { \pi }{ \omega } $$

A particle moves in x-y plane according to the equation $$\overrightarrow {r } =(\hat { i } +2\hat { j })$$ $$A\, cos \,\omega t$$. The motion of the particle is

0%
simple harmonic
0%
uniformly accelerated
0%
circular motion
0%
projectile motion

A particle executes SHM in accordance with x = A sin $$\omega t.$$ If $${ t }_{ 1 }$$ is the time taken by it to reach from x = 0 to x = $$\sqrt { 3 } (A/2)$$ and $${ t }_{ 2 }$$ is the time taken by it to reach from x = $$\left( \sqrt { 3 } /2 \right) A$$ to x = A the value of $${ t }_{ 1 }/{ t }_{ 2 }$$ is

0%
2
0%
$$\dfrac { 1 }{ 2 } $$
0%
3
0%
$$\dfrac { 1 }{ 3 } $$

Equation of SHM is $$x=10\sin{10\pi t}$$. Find the distance between the two points where speed is $$50\pi$$ $$cm/sec$$. $$x$$ is in cm and $$t$$ is in seconds

0%
$$10cm$$
0%
$$20cm$$
0%
$$17.32cm$$
0%
$$5(\sqrt{3}+1) cm$$

The value of phase at maximum displacement from the mean position of a particle in S.H.M. is

0%
$$\pi /2$$
0%
$$\pi $$
0%
Zero
0%
$$2\pi $$

On the basis of dimensions, decide which of the following relations for the displacement of a particle undergoing simple harmonic motion is not correct?

0%
$$ Y = a sin 2 \pi t/ T - cos 2 \pi t / T $$
0%
Y = a sin Vt
0%
$$ y = \dfrac {a}{T} sin \left( \dfrac { Kt }{ a } \right) $$
0%
$$ Y\quad =\quad a\sqrt { 2 } \left( sin\dfrac { 2\pi t }{ T } -cos\dfrac { 2\pi t }{ T } \right) $$

A block of mass $$1 kg$$ is connected with a massless spring of force constant $$100 N/m$$. At $$t=0$$, a constant force $$F=10 N$$ is applied on the block. The spring is in its natural length at $$t=0$$. The speed of particle at $$x=6cm$$ from mean position is:

0%
$$4 cm/s$$
0%
$$10 cm/s$$
0%
$$80 cm/s$$
0%
$$50 cm/s$$

The period of oscillation of a simple pendulum of length $$L$$, suspended from the roof of a vehicle which moves without friction down an inclined plane of inclination $$\alpha$$, is given by:

0%
$$2\pi\sqrt{\left(\dfrac{L}{g\cos \alpha}\right)}$$
0%
$$2\pi\sqrt{\left(\dfrac{L}{g\sin\alpha}\right)}$$
0%
$$2\pi\sqrt{\left(\dfrac{L}{g}\right)}$$
0%
$$2\pi\sqrt{\left(\dfrac{L}{g\tan\alpha}\right)}$$

The equation of an SHM with amplitude $$A$$ and angular frequency $$\omega$$ in which all the distances are measured from one extreme position and time is taken to be zero at the other extreme position is

0%
$$x = A \sin \omega t$$
0%
$$x = A (\cos \omega t + \sin \omega t)$$
0%
$$x = A - A \cos \omega t$$
0%
$$x = A + A \cos \omega t$$

A particle executing SHM has max acceleration $$ 50 cm/s^2 $$ , The time period of oscillation of 2 sec and initial displacement 2.5 cm from the equilibrium position.The equation of SHM is $$ (take\ \pi^2 = 10) $$

0%
$$ X = 2.5 sin \left( \pi t + \frac { \pi }{ 6 } \right) cm $$
0%
$$ X = 5 sin \left( \frac { \pi t }{ 2 } +\frac { \pi }{ 3 } \right) cm $$
0%
$$ X = 5 sin \left( \pi t+\frac { \pi }{ 3 } \right) cm$$
0%
$$X = 5 sin \left( \pi t+\frac { \pi }{ 6 } \right) cm $$

Potential energy of a particle of mass is given by $$U\quad =-\quad { U }_{ 0 }\left( 1-\cos {a x } \right) .$$ which of the following can be a possible expression for its time period

0%
$$2\pi \sqrt { \frac { m }{ { a }^{ 2 }{ u }_{ 0 } } } $$
0%
$$2\pi \sqrt { \frac { m }{ { a }{ u }_{ 0 } } } $$
0%
$$2\pi \sqrt { \frac { ma }{ { U }_{ 0 } } } $$
0%
$$2\pi \sqrt { \frac { { mu }_{ 0 } }{ a } } $$

Between the plates of the capacitor with potential difference $$V$$ across its plate such that upper plate is $$-ve$$, a ball with positive charge '$$q$$' and mass '$$m$$' is suspended by a thread of length '$$l$$'. If the electrostatic force acting on a ball is less than the gravitational force, what should be the period of the ball?

0%
$$T=2\pi\sqrt{\left(\dfrac{l}{g}\right)}$$
0%
$$2\pi\sqrt{\left[\dfrac{1}{\left(g+\dfrac{qE}{m}\right)}\right]}$$
0%
$$T=2\pi\sqrt{\left[\dfrac{1}{\left(g-\dfrac{qE}{m}\right)}\right]}$$
0%
$$2\pi\sqrt{\left(\dfrac{lm}{gE}\right)}$$

A particle of mass m moves in a one-dimensional potential energy $$ U(x) = -ax^2 +bx^4 $$, where a and 'b' are positive constants. the angular frequency of small oscillation about the minima of the potential energy is equal to

0%
$$ \pi \sqrt \frac {a}{2b} $$
0%
$$ 2 \sqrt \frac {a}{m} $$
0%
$$ \sqrt \frac {2a}{m} $$
0%
$$ \sqrt \frac {a}{2m} $$

A particle of mass $$1\ kg$$ is moving where potential energy varies as displacement $$U=10(1-\cos 2x)$$ then:

0%
time period for $$S.H.M.$$ is $$2\pi\sqrt{\dfrac{1}{20}}$$
0%
speed of particle is maximum at $$x=0$$
0%
amplitude of oscillation is $$\dfrac{\pi}{4}$$
0%
time period for $$S.H.M.$$ is $$2\pi\sqrt{\dfrac{1}{40}}$$

A particle of mass $$2\ kg$$ is moving on a straight line under the action of force $$F=(8-2x)N$$. The particle is released at rest from $$x=6\ m$$. For the subsequent motion select the correct options:

0%
equilibrium position at $$x=4$$
0%
amplitude $$=2\ m$$
0%
time to go from $$x=2\ m$$ to $$4\ m $$ is $$ \pi/2$$
0%
energy of S.H.M. $$=4\ J$$

A block of mass $$m$$ is pushed against a spring whose spring constant is $$k$$ fixed at one end with a wall. The block can slide on a frictionless table as shown in figure. If the natural length of spring is $$L_0$$ and it is compressed to half its length when the block is released, find the velocity of the block, when the spring has natural length.

0%
$$\sqrt{\dfrac{m}{k_0}}.\dfrac{L_0}{2}$$
0%
$$\sqrt{\dfrac{3k_0}{m}}.\dfrac{L_0}{2}$$
0%
$$\sqrt{\dfrac{k_0}{m}}.L$$
0%
$$\sqrt{\dfrac{k_0L}{m}}$$

A ball is hung vertically by a thread of length $$l$$ from a point $$P$$ of an inclined wall that makes an angle $$\beta$$ with the vertical. The thread with the ball is then deviated through a small angle $$\alpha(\alpha >\beta)$$ and set free. Assuming the wall to be perfectly elastic, the period of such pendulum is:

0%
$$2\sqrt{\dfrac{l}{g}}\left[\sin^{-1}\left(\dfrac{\beta}{\alpha}\right)\right]$$
0%
$$2\sqrt{\dfrac{l}{g}}\left[\dfrac{\pi}{2}+\sin^{-1}\left(\dfrac{\beta}{\alpha}\right)\right]$$
0%
$$2\sqrt{\dfrac{l}{g}}\left[\cos^{-1}\left(\dfrac{\alpha}{\beta}\right)\right]$$
0%
$$2\sqrt{\dfrac{l}{g}}\left[\cos^{-1}\left(-\dfrac{\beta}{\alpha}\right)\right]$$

The new angular frequency of the system will be:

0%
$$10\ rad/sec$$
0%
$$15\ rad/sec$$
0%
$$20\ rad/sec$$
0%
$$none\ of\ these$$

If an impulse $$J$$ is applied at the centre of oscillation in the plane of oscillation, then angular velocity of the rod will be

0%
$$\dfrac{4J}{ML}$$
0%
$$\dfrac{2J}{ML}$$
0%
$$\dfrac{3J}{2ML}$$
0%
$$\dfrac{J}{ML}$$

The amplitude of oscillation is

0%
$$\dfrac{3}{2\pi}m$$
0%
$$3\ m$$
0%
$$\dfrac{1}{\pi}m$$
0%
$$1.5\ m$$$

A spring balance has a scale that can read from $$0$$ to $$50\ kg$$ . The length of the scale is $$20\ cm$$. A body suspended from this balance when displaced and released oscillates harmonically with a time period of $$0.6\ s$$. The mass of the body is ( take $$g=10\ m/s^2)$$

0%
$$10\ kg$$
0%
$$25\ kg$$
0%
$$18\ kg$$
0%
$$22.8\ kg$$

For the above question locate the centre of oscillation.

0%
$$\dfrac{L}{4}$$ from $$O$$ (down)
0%
$$\dfrac{L}{4}$$ from $$O$$ (up)
0%
$$\dfrac{2L}{3}$$ from $$O$$ (down)
0%
$$\dfrac{7L}{12}$$ from $$O$$ (down)

New equation for position of the combined body is

0%
$$(10+3\sin 5t)\ cm$$
0%
$$(10-3\sin 5t)\ cm$$
0%
$$(10+3\cos 10t)\ cm$$
0%
$$(10-3\cos 10t)\ cm$$

New amplitude of oscillation is

0%
$$3\ cm$$
0%
$$20\ cm$$
0%
$$10\ cm$$
0%
$$100\ cm$$

A particle performs simple harmonic motion with amplitude $$A$$ and time period $$T$$. The mean velocity of the particle over the time in interval which it travels a distance of $$A/2$$ starting from executing position is

0%
$$\dfrac{A}{T}$$
0%
$$\dfrac{2A}{T}$$
0%
$$\dfrac{3A}{T}$$
0%
$$\dfrac{A}{2T}$$

Mark out the correct statement(s).

0%
The block-bullet system performs $$SHM$$ about $$y=mg/k$$
0%
The block-bullet system performs oscillatory motion but not $$SHM$$ about $$y=mg/k$$.
0%
The block-bullet system perform $$SHM$$ about $$y=4\ mg/3k$$.
0%
The block bullet system performs oscillatory motion but not $$SHM$$ about $$y=4\ mg/3k$$

Determine the velocity of particle at $$t=5\ s$$

0%
$$-0.4\ m/s$$
0%
$$0.5\ m/s$$
0%
$$-0.25\ m/s$$
0%
$$none\ of\ these$$

A particle executing harmonic motion is having velocities $$v_1$$ and $$v_2$$ at distances in $$x_1$$ and $$x_2$$ from the equilibrium position. The amplitude of the motion is

0%
$$\sqrt{\dfrac{v_1^2x_2-v_2^2x_1}{v_1^2+v_2^2}}$$
0%
$$\sqrt{\dfrac{v_1^2x_1^2-v_2^2x_2^2}{v_1^2+v_2^2}}$$
0%
$$\sqrt{\dfrac{v_1^2x_2^2-v_2^2x_1^2}{v_1^2-v_2^2}}$$
0%
$$\sqrt{\dfrac{v_1^2x_2^2+v_2^2x_1^2}{v_1^2+v_2^2}}$$

The velocity of the particle when it reaches $$B$$ will be

0%
zero
0%
$$3\sqrt{gl}$$
0%
$$2\sqrt{gl}$$
0%
$$\sqrt{gl}$$

Motion of an oscillating liquid column in a U-tube is

0%
Periodic but not simple harmonic.
0%
non-periodic.
0%
Simple harmonic and time period is independent of the density of the liquid.
0%
Simple harmonic and time-period is directly proportional to the density of the liquid.

A particle doing simple harmonic motion, amplitude $$= 4\ cm$$, time period $$= 12\ sec$$. The ratio between time taken by it in going from its mean position to $$2\ cm$$ and from $$2\ cm$$ to extreme position is

0%
$$1$$
0%
$$1/3$$
0%
$$1/4$$
0%
$$1/2$$

CBSE Questions for Class 11 Engineering Physics Oscillations Quiz 16 - MCQExams.com

0:0:1

Practice Class 11 Engineering Physics Quiz Questions and Answers

CBSE Questions for Class 11 Engineering Physics Oscillations Quiz 16 - MCQExams.com

0:0:1

Practice Class 11 Engineering Physics Quiz Questions and Answers

Support mcqexams.com by disabling your adblocker.