Finding time given positions in SHM

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The discussion revolves around calculating the time it takes for a block attached to a spring to travel from 0.090m to -0.090m when the amplitude is doubled from 0.090m to 0.180m. The period of the spring-mass oscillator remains constant regardless of amplitude, which is a key point in solving the problem. The correct approach involves using the cosine function to determine the times corresponding to the specified positions and then finding the difference between these times. The initial confusion stemmed from the phase of the motion, but clarifying that the times depend solely on position resolved the issue. Ultimately, the solution was successfully achieved by focusing on the relationship between position and time.
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Homework Statement


A small block is attached to an ideal spring and is moving in SHM on a horizontal, frictionless surface. When the amplitude of the motion is 0.090m , it takes the block 2.52s to travel from 0.090m to -0.090m . If the amplitude is doubled, to 0.180m , how long does it take the block to travel from 0.090m to -0.090m ?


Homework Equations


x=Acos(ωt+∅)


The Attempt at a Solution


Ive found the period to be 5.0s, angular frequency to be 1.26 rad/s, and ∅=1.05 rad. Rearranging above equation for time I got (cos-1(x/A)/ω)-∅=t, but this gives me disproportionally large answers. Any suggestions?
 
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On what does the period of a spring-mass oscillator depend? (What's the usual formula for the period)? Do any of the relevant values change when the amplitude is changed?
 
I am aware that the period does not depend on amplitude, however the problem asks for the time taken to cover half of the amplitude. Even with this knowledge I can't figure how to determine this time.
 
Okay. So while the period remains the same, the amplitude has changed. Call the new amplitude B = 0.180 m. Then a function describing position versus time for the oscillator is:

##x(t) = B cos(\omega t)##

You don't need to find a phase, just assume that the function describes the motion beginning at an amplitude maximum. Hence the simple cosine function.

Find the two times corresponding to x1 = 0.090 m and x2 = -0.090 m, and then take the difference.
 
It worked! Thank you very much, it seems that I was thrown off by the phase and was ignoring that the times were dependent upon position and I needed to find the difference between the two.
 
jstevenson16 said:
It worked! Thank you very much, it seems that I was thrown off by the phase and was ignoring that the times were dependent upon position and I needed to find the difference between the two.

Excellent. Glad it worked out!
 

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