Both Assertion and Reason are correct and Reason is the correct explanation for Assertion

Both Assertion and Reason are correct but Reason is not the correct explanation for Assertion

Assertion is correct but Reason is incorrect

Assertion is incorrect but Reason is correct

MCQ Questions for Class 12 Medical Physics Electromagnetic Induction Quiz 5

When the current in a coil changes from 2 amp. to 4 amp. in 0.05 sec., an e.m.f. of 8 volt induced in the coil. The coefficient of self inductance of the coil is

0%
0.1 henry
0%
0.2 henry
0%
0.4 henry
0%
0.8 henry

A copper disc of radius $$0.1$$ $$m$$ rotated about its centre with $$10$$ revolutions per second in a uniform magnetic field of $$0.1$$ tesla with it's plane perpendicular to the field. The e.m.f. induced across the radius of disc is:

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$$\dfrac {\pi}{10}volt$$
0%
$$\dfrac {2\pi}{10}volt$$
0%
$$\pi \times 10^{-2}volt$$
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$$2\pi \times 10^{-2}volt$$

Magnetic flux $$\phi$$, in weber, in a closed circuit of resistance $$10\Omega$$ varies with time $$t$$ in seconds as $$\phi=6t^2-5t+1$$. The magnitude of induced current at $$t=0.25 s$$ is :

0%
0.2 A
0%
0.6 A
0%
1.2 A
0%
0.8 A

A cylindrical bar magnet is kept along the axis of a circular coil. On rotating the magnet about its axis, the coil will have induced in it

0%
a current
0%
no current
0%
only an e.m.f.
0%
both an e.m.f. and a current

The coefficient of mutual inductance between two coils depends on

0%
medium between the coils
0%
separation between the two coils
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orientation of the two coils
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all of the above

A solenoid that is highly wound with wire of diameter $$0.10cm$$ has a cross-sectional area $$0.90{cm}^{2}$$ and is $$40cm$$ long. Calculate the self inductance of the solenoid.

0%
$$4.5 \times 10^{-5} H$$
0%
$$7.5 \times 10^{-5} H$$
0%
$$10 \times 10^{-5} H$$
0%
$$12.5 \times 10^{-5} H$$

A horizontal telegraph wire $$0.5\ km$$ long running east and west in a part of a circuit whose resistance is $$2.5\ \Omega$$. The wire falls to $$g=10.0\ m/s^2$$ and $$B=2\times 10^{-5} weber/m^2$$, then the current induced in the circuit is

0%
$$0.7\ amp$$
0%
$$0.04\ amp$$
0%
$$0.02\ amp$$
0%
$$0.01\ amp$$

Which of the following units denotes the dimension $$\dfrac {ML^2}{Q^2}$$ where Q denotes the electric charge?

0%
$$Wb/m^2$$
0%
$$henry (H)$$
0%
$$H/m^2$$
0%
$$weber (Wb)$$

If coefficient of self induction of a coil is 1 H, an e.m.f. of 1 V is induced, if

0%
current flowing is 1 A
0%
current variation rate is 1 $$As^{-1}$$
0%
current of 1A flows for one sec
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none of these

The two rails of a railway track, insulated from each other and the ground, are connected to millivoltmeter. What is the reading of the millivoltmeter when a train passes at a speed of 180 km/hr along the track, given that the vertical component of earth's magnetic field is $$0.2\times 10^{-4}wb/m^2$$ and rails are separated by 1 metre

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$$10^{-1} volt$$
0%
$$10 \ mV$$
0%
$$1 \ volt$$
0%
$$1 \ mV$$

A metal conductor of length 1 m rotates vertically about one of its ends at angular velocity 5 radians per second. If the horizontal component of earth's magnetic field is $$0.2\times 10^{-4}T$$, then the e.m.f developed between the two ends of the conductor is

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5 mV
0%
$$50\mu V$$
0%
$$5\mu V$$
0%
50 mV

The flux linked with a coil at any instant 't' is given by $$\phi=10t^2-50t+250$$. The induced emf at $$t=3s$$ is

0%
-190 V
0%
-10 V
0%
10 V
0%
190 V

The current in a coil of $$L=40 mH$$ is to be increased uniformly from $$1A$$ to $$11A$$ in $$4$$ milliseconds. The induced e.m.f. will be

0%
$$100 V$$
0%
$$0.4V$$
0%
$$440 V$$
0%
$$40V$$

The dimensions of self inductance are

0%
$$\left[ ML{ T }^{ -2 }{ A }^{ -2 } \right] $$
0%
$$\left[ M{ L }^{ 2 }{ T }^{ -1 }{ A }^{ -2 } \right] $$
0%
$$\left[ M{ L }^{ 2 }{ T }^{ -2 }{ A }^{ -2 } \right] $$
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$$\left[ M{ L }^{ 2 }{ T }^{ -1 }{ A }^{ - 1} \right] $$

A conducting rod is rotating about one end in a plane perpendicular to a uniform magnetic field with constant angular velocity. The correct graph between the induced emf($$e$$) across the rod and time ($$t$$) is

A solenoid that is highly wound with wire of diameter $$0.10cm$$ has a cross-sectional area $$0.90{cm}^{2}$$ and is $$40cm$$ long. If the current through the solenoid decreases uniformly from $$10A$$ to $$0A$$ in $$0.10s$$, what is the emf induced between the ends of the solenoid?

0%
$$4.5 \times 10^{-4} V$$
0%
$$5.5 \times 10^{-3} V$$
0%
$$5.0 \times 10^{-8} V$$
0%
$$4.5 \times 10^{-3} V$$

In figure, if the current $$i$$ decreases at a rate $$\alpha$$, then $${V}_{A}-{V}_{B}$$ is

0%
zero
0%
$$-\alpha L$$
0%
$$\alpha L$$
0%
No relation exists

The current $$i$$ in an induction coil varies with time $$t$$ according to the graph shown in the figure. Which of the following graphs shows the induced emf ($$\varepsilon $$) in the coil with time?

In figure, there is a conducting ring having resistance $$R$$ placed in the plane of paper in a uniform magnetic field $${B}_{0}$$. If the ring is rotating in the plane of paper about an axis passing through point $$O$$ and perpendicular to the plane of paper with constant angular speed $$\omega$$ in clockwise direction, then

0%
point $$O$$ will be at higher potential than $$A$$
0%
the potential of point $$B$$ and $$C$$ will different
0%
the current in the ring will be zero
0%
the current in the ring will be $$2{B}_{0}\omega {r}^{2}/R$$
0%
answer required

Which of the following statement best describe the Faraday's Law?

0%
the induced voltage in a coil is proportional to the number of turns in the coil and to the rate at which the magnetic field is changing
0%
the induced voltage in a coil is equal to the rate at which the magnetic field is changing
0%
the induced voltage in a coil is proportional to the number of turns in the coil and to the strength of the magnetic field
0%
the induced voltage in a coil is proportional to the number of turns in the coil and to the size of the magnetic field
0%
the induced voltage in a coil proportional to the number of turns in the coil and to the source of the magnetic field

An equilateral triangular conducting frame is rotated with angular velocity $$\omega$$ in uniform magnetic field $$B$$ as shown. Side of triangle is $$l$$. Choose the correct options

0%
$${V}_{a}-{V}_{c}=0$$
0%
$${V}_{a}-{V}_{c}=\cfrac { B\omega { l }^{ 2 } }{ 2 } $$
0%
$${V}_{a}-{V}_{b}=\cfrac { B\omega { l }^{ 2 } }{ 2 } $$
0%
$${V}_{c}-{V}_{b}=-\cfrac { B\omega { l }^{ 2 } }{ 2 } $$

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Both Assertion and Reason are correct and Reason is the correct explanation for Assertion
0%
Both Assertion and Reason are correct but Reason is not the correct explanation for Assertion
0%
Assertion is correct but Reason is incorrect
0%
Assertion is incorrect but Reason is correct

A metal disc of radius $$a$$ rotates with a constant angular velocity $$\omega$$ about its axis. The potential difference between the center and the rim of the disc is ($$m=$$ mass of electron, $$e=$$ charge on electron)

0%
$$\cfrac{m{\omega}^{2}{a}^{2}}{e}$$
0%
$$\cfrac { 1 }{ 2 } \cfrac{m{\omega}^{2}{a}^{2}}{e}$$
0%
$$\cfrac{e{\omega}^{2}{a}^{2}}{2m}$$
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$$\cfrac{e{\omega}^{2}{a}^{2}}{m}$$

A metal rod of resistance $$20\Omega$$ is fixed along a diameter of a conducting ring of radius $$0.1m$$ and lies on x-y plane. There is a magnetic field $$\vec { B } =\left( 50T \right) \hat { K } $$. The ring rotates with an angular velocity $$\omega=20rad$$ $${s}^{-1}$$ about its axis. An external resistance of $$10\Omega$$ is connected across the center of the ring and rim. The current through external resistance is:

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$$\cfrac{1}{4}$$
0%
$$\cfrac{1}{2}$$
0%
$$\cfrac{1}{3}$$
0%
zero

Two identical cycle wheels (geometrically) have different number of spokes connected from center to rim. One is having $$20$$ spokes and the other having only $$10$$ (the rim and the spokes are resistanceless). One resistance of value $$R$$ is connected between center and rim. The current in $$R$$ will be

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double in the first wheel than in the second wheel
0%
four times in the first wheel than in the second wheel
0%
will be double in the second wheel than that of the first wheel
0%
will be equal in both these wheels
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answer required

A uniform magnetic field exists in a region given by $$\vec { B } =3\hat { i } +4\hat { j } +5\hat { k } $$. A rod of length $$5m$$ along y-axis moves with a constant speed of $$1m$$ $${s}^{-1}$$ along x axis. Then the induced emf in the rod will be

0%
$$0$$
0%
$$25V$$
0%
$$20V$$
0%
$$15V$$
0%
none

When an $$AC$$ signal of frequency $$1kHz$$ is applied across a coil of resistance $$100\Omega$$, then the applied voltage leads the current by $$45^o$$. The inductance of the coil is:

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$$16mH$$
0%
$$12mH$$
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$$8mH$$
0%
$$4mH$$

A rectangular coil $$ABCD$$ is rotated anticlockwise with a uniform angular velocity about the axis shown in figure. The axis of rotation of the coil as well as the magnetic field $$B$$ is horizontal. The induced emf in the coil would be minimum when the plane of the coil

0%
is horizontal
0%
makes and angle $${45}^{o}$$ with direction of magnetic field
0%
is at right angle to the magnetic field
0%
makes and angle of $${30}^{o}$$ with the magnetic field
0%
answer required

Study involving both electricity and magnetism is called ______.

0%
electromagnetism
0%
magnetoelectricism
0%
electricmagnetism
0%
magneticelectromerism

A conducting ring of radius $$r$$ and resistance $$R$$ rolls on a horizontal surface with constant velocity $$v$$. The magnetic field $$B$$ is uniform and is normal to the plane of the loop. Choose the correct option.

0%
The induced emf between $$O$$ and $$Q$$ is $$Brv$$
0%
An induced current $$I=\cfrac{2Bvr}{R}$$ flows in the clockwise direction
0%
An induced current $$I=\cfrac{2Bvr}{R}$$ flows in the anticlockwise direction
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No current flows
0%
answer required

A metal rod moves at a constant velocity in a direction perpendicular to its length. A constant uniform magnetic field exists in space in a direction perpendicular to the rod as well as its velocity. Select the correct statement(s) from the following:

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The entire rod is at the same electric potential
0%
There is an electric field in the rod
0%
The electric potential is highest at the center of the rod and decrease toward its ends
0%
The electric potential is lowest at the center of the rod and increases toward its ends

A conductor $$AB$$ of length $$l$$ moves in x-y plane with velocity $$\vec { v } ={ v }_{ 0 }\left( \hat { i } -\hat { j } \right) $$. A magnetic field $$\vec { B } ={ B }_{ 0 }\left( \hat { i } +\hat { j } \right) $$ exists in the region. The induced emf is

0%
zero
0%
$$2{B}_{0}l{v}_{0}$$
0%
$${B}_{0}l{v}_{0}$$
0%
$$\sqrt {2} {B}_{0}l{v}_{0}$$

The conductor $$AD$$ moves to the right in a uniform magnetic field directed into the plane of the paper.

0%
The free electron in $$AD$$ will move toward $$A$$
0%
$$D$$d will acquire a positive potential with respect to $$A$$
0%
$$A$$ current will flow from $$A$$ to $$D$$ in $$AD$$ in closed loop
0%
The current in $$AD$$ flows from lower to higher potential
0%
answer required

A vertical conducting ring of radius $$R$$ falls vertically in a horizontal magnetic field of magnitude $$B$$. The direction of $$B$$ is perpendicular to the plane of the ring. When the speed of the ring is $$v$$,

0%
no current flows in the ring
0%
$$A$$ and $$D$$ are at the same potential
0%
$$C$$ and $$E$$ are at the same potential
0%
the potential difference between $$A$$ and $$D$$ is $$2BRv$$, with $$D$$ at a higher potential
0%
answer required

The magnetic flux through a circuit of resistance 'R' changes by an amount $$\Delta \Phi$$ at a time $$\Delta t$$. Then the total quantity of electric charge Q that passes any point in the circuit during the time $$\Delta t $$ is represented by

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$$Q = \displaystyle \frac{\Delta \Phi}{R}$$
0%
$$Q= \displaystyle \frac{\Delta \Phi}{\Delta t}$$
0%
$$Q= \displaystyle R. \frac{\Delta \Phi}{\Delta t}$$
0%
$$Q = \displaystyle {1}{R} . \frac{\Delta \Phi}{\Delta t}$$

Comment on the statement given below:

In self-induction

When the current in a coil is increasing, induced emf opposes it
When the current in a coil is decreasing, induced emf supports it

0%
A is true, B is false
0%
A and B are false
0%
A and B are true
0%
A is false, B is true

Which of the following statement is correct regarding induced electric field (symbols have their usual meanings)?

0%
Work done in moving a test charge in an induced electric field can be zero
0%
Induced electric field is non-conservative is nature
0%
Induced electric lines of force form closed loops
0%
Induced e.m.f. in the loop in $$\displaystyle \varepsilon =\oint \overrightarrow{E}.\overline{d\iota }=-\frac{d\phi }{dt}$$

A magnetic field of flux density 1.0 Wb $$m^{-2}$$ acts normal to a 80 tum coil of 0.01 $$m^2$$ area. The e.m.f. induced in it, if this coil is removed from the field in 0.1 second is :

0%
8V
0%
4V
0%
10V
0%
6V

A wire 88 cm long bent into a circular loop is placed perpendicular to the magnetic field of flux density 2.5 Wb $$m^{-2}$$. Within 0.5 s, the loop is changed into a square and flux density is increased to 3.0 Wb $$m^{-2}$$. The value of e.m.f. induced is :

0%
0.018V
0%
0.016V
0%
0.020V
0%
0.012V

Which of the following electrical devices works on the principle of electro-magnetic induction ?

0%
Electric fan
0%
Electric bulb
0%
Electric cooker
0%
L.E.D.

A magnet is moved into the coil of wire as shown, there is a small reading on the sensitive meter.
Which change would increase the size of the reading ?

0%
Moving the south pole in
0%
Pulling the magnet out
0%
Pushing the magnet in faster
0%
Unwinding some of the turns of wire

The simplest type of AC voltage or current is the one which

0%
Varies exponentially
0%
Varies sinusoidally
0%
Varies linearly
0%
Does not vary uniformly

The current flowing through the primary coil of mutual inductance 8 H is reduced to zero in $$10^{-3}$$s. As a result of which a $$24\times 10^3$$ V is induced in the secondary. The initial current through the primary is _____A.

0%
2
0%
1
0%
4
0%
3

What will be the magnitude of e.m.f. induced in a 200 turns coil with cross section area 0.16 $$m^2$$ if the magnetic field through the coil changes from 0.10 Wb $$m^{-2}$$ to 0.30 $$m^{-2}$$ in 0.05 second.

0%
128V
0%
130V
0%
118V
0%
132V

The variation of anode current in a triode valve corresponding to a change in grid potential at three different values of the plate potential is shown in the given figure. The mutual conductance of triode is

0%
$$5\times {10}^{-3} mho$$
0%
$$2.5\times {10}^{-3} mho$$
0%
$$7.5\times {10}^{-3} mho$$
0%
$$9.5\times {10}^{-3} mho$$

Consider a current carrying coil placed in a magnetic field. What are the requirements for induced current to flow as per electromagnetic induction.

0%
Coil of wire carrying current
0%
Change in magnetic field associated with the coil
0%
Both A and B
0%
None

When the coil and the magnet are both stationary

0%
there is no deflection in the galvanometer.
0%
galvanometer deflects.
0%
galvanometer bursts.
0%
none

A jet plane is travelling towards west at a speed of 1600 km/h. What is the voltage difference developed between the ends of the wing having a span of 25 m, if the Earths magnetic field at the location has a magnitude of 5 $$\times 10^{-4}$$ T and the dip angle is $$30^o$$.

0%
4.1 V
0%
2.2 V
0%
3.2 V
0%
3.8 V

If a current carrying coil is close to a magnet and both are moving with the same speed in same direction, what is the effect on induced current ?

0%
Induced current increases
0%
Induced current decreases
0%
Induced current flows to oppose motion
0%
Induced current remains equal to zero

What is the self inductance of a coil in which an induced emf of $$2V$$ is set up, when the current is changing at the rate of $$4As^{-1}$$

0%
$$0.5\ mH$$
0%
$$0.05\ H$$
0%
$$2\ H$$
0%
$$0.5\ H$$

CBSE Questions for Class 12 Medical Physics Electromagnetic Induction Quiz 5 - MCQExams.com

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Practice Class 12 Medical Physics Quiz Questions and Answers

CBSE Questions for Class 12 Medical Physics Electromagnetic Induction Quiz 5 - MCQExams.com

0:0:1

Practice Class 12 Medical Physics Quiz Questions and Answers

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