Simple Harmonic Motion of a 2kg particle

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Homework Help Overview

The discussion revolves around a 2kg particle undergoing simple harmonic motion, described by the equation x=1.5sin((pi*t/4) + Pi/6). Participants are exploring how to calculate the total mechanical energy of the particle and the time taken for the particle to move between specific positions.

Discussion Character

  • Exploratory, Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • Participants are attempting to understand the relationship between potential energy (PE) and kinetic energy (KE) in the context of total mechanical energy. Questions arise about the appropriate values for spring constant (k) and displacement (x) to use in calculations. Some participants suggest that maximum potential energy corresponds to maximum displacement, while others question the need for calculus in solving the problem.

Discussion Status

There is an ongoing exploration of how to approach the problem, with some participants providing insights into the relationship between energy forms in simple harmonic motion. Guidance has been offered regarding the use of maximum potential energy and the relationship between k and the frequency of the oscillator. However, no consensus has been reached on the specific values or methods to apply.

Contextual Notes

Participants express confusion regarding the teacher's explanations and the necessary concepts for solving the problem, indicating a potential gap in foundational understanding. There is also mention of constraints related to the information provided in the problem statement.

chewytess
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Homework Statement


A 2kg particle undergoes simple harmonic motion according to x=1.5sin((pi*t/4) + Pi/6)

A)What is the total mechanical energy of the particle?
B) Shortest time for particle to go from x=.5m to x=-.75m

Homework Equations


Potential energy=.5kx^2

The Attempt at a Solution



I don't get what to use for k or x to find the total energy. Please help?
 
Last edited:
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The general equation for SHM is x=Asin(ωt+Φ). The total energy is a sum of the KE and PE of the system (which are interchanged as time passes). So when KE increase, PE decreases and vice versa.

So what happens when the PE reaches zero, shouldn't the KE reach the maximum value (the total energy of the system)?

I think you know KE = ½mv2 and v= dx/dt.
 
I don't get what to use for k or x to find the total energy. Please help?

k and x only give you the potential energy, right? But the total energy is kinetic energy plus potential energy,

E = KE + PE

How do we deal with kinetic energy?

Edit to include this:

I think you know KE = ½mv2 and v= dx/dt.

I don't think that's right right way to go here. OP might not know enough calculus yet, and you can do the problem without it.
 
I know that the kinetic energy plus the potential energy is equal to the totalt energy. I know the easiest way to solve the problem would just be to find one of them at the max. I am just confused on which one to solve for and how. My teacher did a really bad job on explaning this chapter and I am just trying to get some insight on this to help me better understand. Thnx
 
chewytess said:
I know that the kinetic energy plus the potential energy is equal to the totalt energy. I know the easiest way to solve the problem would just be to find one of them at the max. I am just confused on which one to solve for and how. My teacher did a really bad job on explaning this chapter and I am just trying to get some insight on this to help me better understand. Thnx

You'll either have at max:

KEmax = 0.5mv2

OR

PEmax = 0.5kx2

with the constraints of the problem being either given m or k, which do you think you should use?
 
I think i should find the max pe. I am just confused on what numbers to use
 
So, like you said we need k and x.

1. Maximum PE means maximum x, right? What's the maximum x-value? If you're stuck, try graphing your equation from the first post.

2. k is related to the frequency of the oscillator. This should make some sense; a stiffer spring will oscillate quicker. Your book should have an equation that relates the period (or frequency) of the motion to the spring constant of the spring.
 
Thank you it finally clicked, your help is much appreciated!
 

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