Mass - Spring - damper in Parallel

AI Thread Summary
The discussion focuses on determining the transfer function for a mass-spring-damper system, specifically addressing the input force and output displacement. The participant confirms that their differential equations are correct but seeks clarification on the methodology for deriving the transfer function and its inverse Laplace transform. They express difficulty in obtaining the time-domain output and are concerned about the implications of having a damping ratio greater than one, which leads to complex values. Suggestions include factoring the denominator and using partial fractions to simplify the process. Overall, the conversation emphasizes the importance of accurately applying Laplace transforms in mechanical systems analysis.
kjay262
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Homework Statement


The problem is to determine the transfer function where force F is input and displacement x is output in the mass-spring-damper mechanism.

Homework Equations


Spring Force = kx [k:spring constant]
Damping Force = Cx [C:damping coefficient]
Force = (Mass)(acceleration)

The Attempt at a Solution


Attempt at solution is in picture. I am interested to know if I am following the correct methodology and if I am missing anything.
 

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  • 10273955_10154109711405307_3235781433148029459_n.jpg
    10273955_10154109711405307_3235781433148029459_n.jpg
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****EDIT**** not in parallel, IN SERIES
 
The differential equations look correct. That was the hard part. I haven't look over the part about the development of the transform, but that shouldn't have been a problem.

Chet
 
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If the input force is a unit impulse the transfer function is equal to the output displacement in the complex domain. I'm struggling to determine the x(t) that is the output in the time domain, which is basically the inverse laplace of the transfer function. I using the identity (attached below), however the answer introduces a complex value, am I missing something.
 
Last edited:
Inverse Laplace Identity

Using the identity attached to determine the inverse laplace of the transfer function
 

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  • Screenshot 2014-05-21 13.11.30.png
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Multiply numerator and denominator by cs+k. See if this simplifies things.

Chet
 
What if you have a situation where \xi is greater than one (according to the identity image attached above) this would result in a complex number, yes? How would that be represented in graph?
 
kjay262 said:
What if you have a situation where \xi is greater than one (according to the identity image attached above) this would result in a complex number, yes? How would that be represented in graph?
Factor the denominator using the quadratic formula, and then resolve the transform into partial fractions, and you will then be able to answer your own question.
 
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