Oscillations MCQs | 100 Questions | Class 11 Physics
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Oscillations MCQs with Answers – Part 4 (Class 11 Physics)

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301. An overdamped oscillator differs from a lightly damped oscillator because the overdamped oscillator
ⓐ. returns without repeated equilibrium crossings
ⓑ. oscillates with constant amplitude forever
ⓒ. loses the restoring tendency at all displacements
ⓓ. gains amplitude after each attempted cycle
302. A displacement-time record shows that an oscillator crosses the mean position many times, but the peak displacement after each crossing is smaller than before. The motion is best classified as
ⓐ. undamped SHM
ⓑ. lightly damped oscillation
ⓒ. critically damped motion
ⓓ. overdamped non-oscillatory motion
303. A damped spring oscillator has its amplitude reduced from \(A_0\) to \(\frac{A_0}{2}\). If its mechanical energy is proportional to the square of amplitude, the remaining energy is
ⓐ. \(\frac{E_0}{2}\)
ⓑ. \(\frac{E_0}{4}\)
ⓒ. \(2E_0\)
ⓓ. \(4E_0\)
304. Study the table comparing damped motion cases.
RowDamping caseBehavior
PLight dampingOscillates with decreasing amplitude
QCritical dampingReturns fastest without oscillation
ROverdampingReturns slowly without oscillation
SUndamped ideal motionAmplitude decreases due to resistive loss
The row that is not suitable is
ⓐ. Row P
ⓑ. Row Q
ⓒ. Row R
ⓓ. Row S
305. A free oscillator is one that, after being disturbed and released, oscillates mainly with
ⓐ. its natural frequency
ⓑ. the frequency of an external driver only
ⓒ. zero frequency at all amplitudes
ⓓ. a frequency chosen independently of the system
306. In forced oscillations, the oscillator is acted on by
ⓐ. a constant force only
ⓑ. a periodic external force
ⓒ. no external influence after release
ⓓ. a force always proportional to speed in the same direction
307. A child on a swing is pushed periodically. The amplitude grows large when the pushes are timed so that their frequency is close to the swing’s natural frequency. This is an example of
ⓐ. critical damping
ⓑ. resonance
ⓒ. uniform circular motion
ⓓ. overdamping
308. In steady forced oscillation, the frequency of the oscillator is mainly equal to
ⓐ. the driving frequency
ⓑ. zero at all times
ⓒ. twice the amplitude
ⓓ. the damping constant only
309. A driven oscillator has natural frequency \(f_0=5\,\text{Hz}\). It is driven successively by external forces of frequencies \(2\,\text{Hz}\), \(4.8\,\text{Hz}\), \(8\,\text{Hz}\), and \(12\,\text{Hz}\). The largest amplitude is expected near
ⓐ. \(2.0\,\text{Hz}\)
ⓑ. \(4.8\,\text{Hz}\)
ⓒ. \(8.0\,\text{Hz}\)
ⓓ. \(12.0\,\text{Hz}\)
310. Use the graph description below.
The amplitude of a driven oscillator is plotted against driving frequency. The curve has a peak near the natural frequency of the oscillator.
The peak of the curve represents
ⓐ. maximum response due to resonance
ⓑ. zero energy transfer from the driver
ⓒ. motion with no restoring force
ⓓ. overdamped return without oscillation
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