Oscillations MCQs set 2 for NTS NAT-IE (Engineering Track) Physics — 20 solved questions.
Q1. The motion of a simple pendulum is an example of
Answer: Simple harmonic motion
Explanation: Pendulum's motion is periodic and follows SHM equation d²θ/dt² = - (g/l) θ, where g is acceleration due to gravity and l is length.
Q2. The time period of a simple pendulum is given by
Answer: 2π √(l/g)
Explanation: Derived from SHM equation, time period T = 2π √(l/g), where l is pendulum length and g is acceleration due to gravity.
Q3. The frequency of oscillation of a mass-spring system is
Answer: (1/2π) √(k/m)
Explanation: Frequency f = (1/2π) √(k/m), where k is spring constant and m is mass attached to the spring.
Q4. The total energy of a simple harmonic oscillator is
Answer: Proportional to amplitude ²
Explanation: Total energy E = (1/2) m ω² A², where ω is angular frequency and A is amplitude, so E ∝ A².
Q5. The equation of simple harmonic motion is given by
Answer: d²x/dt² + ω² x = 0
Explanation: SHM is represented by d²x/dt² + ω² x = 0, where ω is angular frequency and x is displacement.
Q6. The angular frequency of a mass-spring system is
Answer: √(k/m)
Explanation: Angular frequency ω = √(k/m), where k is spring constant and m is mass.
Q7. The time period of a physical pendulum is given by
Answer: 2π √(I/mgd)
Explanation: Time period T = 2π √(I/mgd), where I is moment of inertia, m is mass, g is acceleration due to gravity, and d is distance from pivot to center of mass.
Q8. The amplitude of a damped oscillator decreases exponentially with
Answer: Time
Explanation: Amplitude A(t) = A₀ e^(-bt), where b is damping coefficient, so amplitude decreases exponentially with time.
Q9. The resonance occurs when the frequency of the external force is
Answer: Equal to the natural frequency
Explanation: Resonance occurs when driving frequency matches natural frequency, maximizing amplitude.
Q10. The quality factor of a damped oscillator is given by
Answer: ω₀ / (2b)
Explanation: Quality factor Q = ω₀ / (2b), where ω₀ is natural frequency and b is damping coefficient.
Q11. The equation of a damped oscillator is given by
Answer: d²x/dt² + 2b dx/dt + ω₀² x = 0
Explanation: Damped oscillator is represented by d²x/dt² + 2b dx/dt + ω₀² x = 0, where b is damping coefficient and ω₀ is natural frequency.
Q12. The energy of a simple harmonic oscillator is proportional to
Answer: Amplitude ²
Explanation: Total energy E = (1/2) m ω² A², so E ∝ A², where A is amplitude.
Q13. The maximum velocity of a simple harmonic oscillator is
Answer: Aω
Explanation: Maximum velocity v_max = Aω, where A is amplitude and ω is angular frequency.
Q14. The maximum acceleration of a simple harmonic oscillator is
Answer: Aω²
Explanation: Maximum acceleration a_max = Aω², where A is amplitude and ω is angular frequency.
Q15. The simple harmonic motion is represented by
Answer: Both A and B
Explanation: SHM can be represented by x = A sin(ωt + φ) or x = A cos(ωt + φ), both are valid representations.
Q16. The frequency of a simple pendulum on the surface of the earth and at height h above it are related as
Answer: f_h = f₀ √(R / (R + h))
Explanation: Frequency f ∝ √g, and g at height h is g_h = g₀ (R / (R + h))², so f_h = f₀ √(R / (R + h)).
Q17. The time period of a simple pendulum in a lift accelerating upwards is
Answer: 2π √(l / (g + a))
Explanation: Effective g is g + a when lift accelerates upwards, so T = 2π √(l / (g + a)).
Q18. The time period of a simple pendulum in a lift accelerating downwards is
Answer: 2π √(l / (g - a))
Explanation: Effective g is g - a when lift accelerates downwards, so T = 2π √(l / (g - a)).
Q19. The graph between time period and length of a simple pendulum is
Answer: Parabolic
Explanation: T = 2π √(l/g), so T² ∝ l, a parabolic relation between T and √l.
Q20. A simple pendulum has a time period T. What will be its new time period if its length is doubled?
Answer: T √2
Explanation: T = 2π √(l/g). When l is doubled, T becomes √2 times. So, new T = T √2.