Class 11PhysicsOscillationsDifferent types of oscillations (Free, Damped, Forced Oscillation and Resonance)
MediumExplain the behaviour of the oscillator when the driving frequency is far from the natural frequency in small damped oscillations.
(N/A) For small damping,the amplitude $A$ of a forced oscillator is given by $A = \frac{F_0}{\sqrt{m^2(\omega^2 - \omega_d^2)^2 + (\omega_d b)^2}}$.
When the driving frequency $\omega_d$ is far from the natural frequency $\omega$,such that $\omega_d b << m|\omega^2 - \omega_d^2|$,the term $(\omega_d b)^2$ can be neglected in the denominator.
Thus,the amplitude simplifies to $A \approx \frac{F_0}{m|\omega^2 - \omega_d^2|}$.
In this regime,the amplitude is primarily determined by the stiffness and inertia of the system rather than the damping constant $b$. As $\omega_d$ moves further away from $\omega$,the amplitude decreases significantly.
When $\omega_d = \omega$,the amplitude is limited only by the damping term,$A = \frac{F_0}{\omega_d b}$. If $b = 0$,the amplitude becomes infinite at resonance. As damping $b$ increases,the peak amplitude decreases and shifts slightly.
When the driving frequency $\omega_d$ is far from the natural frequency $\omega$,such that $\omega_d b << m|\omega^2 - \omega_d^2|$,the term $(\omega_d b)^2$ can be neglected in the denominator.
Thus,the amplitude simplifies to $A \approx \frac{F_0}{m|\omega^2 - \omega_d^2|}$.
In this regime,the amplitude is primarily determined by the stiffness and inertia of the system rather than the damping constant $b$. As $\omega_d$ moves further away from $\omega$,the amplitude decreases significantly.
When $\omega_d = \omega$,the amplitude is limited only by the damping term,$A = \frac{F_0}{\omega_d b}$. If $b = 0$,the amplitude becomes infinite at resonance. As damping $b$ increases,the peak amplitude decreases and shifts slightly.
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