Resonance gets sharper just by increasing the resonance freq, why?

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Aaron121
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The ##Q## factor of an oscillating system is defined as ##\omega_{r}/\Delta \omega##, where ##\omega_{r}## is the resonant frequency, and ##\Delta \omega## the resonance width. As I understand, ##Q## measures how sharp the resonance curve is.

Why is it that the resonance curve gets sharper (higher ##Q##) just by virtue of having a higher resonant frequency, while keeping the same width ##\Delta \omega## ?
 
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@BvU For example, for a damped, driven harmonic oscillator with a natural frequency ##\omega_{0}##, the cutoff frequencies are at ##\sqrt{\omega_{0}^2+\frac{\gamma ^2}{4}}\pm \frac{\gamma}{2}##, where ##\gamma## is the damping coefficient. The equation of motion of the oscillator is given by ##\ddot{x}(t)+\gamma \dot{x}(t)+\omega_{0}^2 x(t)=F(t)/m##, (see page ##10## of this document). ##\Delta \omega##, in this case, is simply ##\gamma##, which doesn't depend on the resonant frequency ##\omega _{r}=\omega _{0}##.
 
##\gamma## is the proportionality factor between the friction force ##\textbf{f}_{r}## and the velocity ##\dot{\textbf{x}}(t)##, i.e., ##\textbf{f}_{r}=-\gamma \dot{\textbf{x}}(t)##. The friction force is a viscous one.
 
Aaron121 said:
##\gamma## is the proportionality factor between the friction force ##\textbf{f}_{r}## and the velocity ##\dot{\textbf{x}}(t)##, i.e., ##\textbf{f}_{r}=-\gamma \dot{\textbf{x}}(t)##. The friction force is a viscous one.
That has the rate of change of x in it - aka proportional to FREQUENCY boom boom.