Oscillation:Resonant frequency in vacuum

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The discussion centers on the concept of resonant frequency and its effects on oscillation amplitude. When a pendulum is forced to oscillate at its resonant frequency, the amplitude can theoretically increase indefinitely, especially in a vacuum where damping is minimal. The analogy of pushing a swing illustrates that applying force at the correct timing enhances amplitude, while incorrect timing can disrupt motion. The key takeaway is that resonant frequency allows for maximum energy transfer, leading to increased oscillation amplitude. Understanding this principle is crucial for grasping the behavior of oscillating systems.
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Homework Statement


A pendulum is constructed from a fixed length of light thread and and a spherical,low density,polystyrene bob.It is forced to oscillate at a different frequencies in air,and the response is shown in the graph below.
363990__image527058.jpg


Homework Equations


The Attempt at a Solution



363990__image527062.jpg

This is the answer.I have googled it and still need explanation regarding how does ringing something at resonant frequency in vacuum causes the amplitude to tend to infinity.

Thanks for your help!
 
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Well that's basically what the resonant frequency is

Don't take this too literally as it's not quite the exact same thing, but to help understand resonance, let's say I'm pushing you on a swing. So I'm applying a periodic force at some frequency and you're oscillating back and forth. What happens if I apply the force too early while you're still coming back at me? Do I increase your amplitude? No you knock me on my butt. What if I wait too long? I fall on my face

But what if I apply the force at jussst the right time? I increase your amplitude. So if you're applying the force at just the right times (the resonant frequency) to the pendulum bob, you increase its amplitude every time without screwing up its own periodic motion, so it increases and increases
 

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