Energy of simple harmonic oscillator

Click For Summary
SUMMARY

The discussion focuses on the energy of a simple harmonic oscillator, specifically analyzing the kinetic energy (K) and potential energy (P) as functions of time (t). The equations used include K = (1/2)m*v^2 and P = (1/2)k*x^2, with the motion described by x = Asin(wt + τ) and v = Aωcos(wt + τ). The total energy (E) is shown to be constant by applying the trigonometric identity cos²(x) + sin²(x) = 1, confirming that K + P remains constant over time.

PREREQUISITES
  • Understanding of simple harmonic motion
  • Familiarity with kinetic and potential energy equations
  • Knowledge of trigonometric identities
  • Basic calculus for differentiation
NEXT STEPS
  • Study the derivation of simple harmonic motion equations
  • Learn about energy conservation in oscillatory systems
  • Explore the relationship between angular frequency (ω) and spring constant (k)
  • Investigate the role of damping in harmonic oscillators
USEFUL FOR

Students studying physics, particularly those focusing on mechanics and oscillatory motion, as well as educators seeking to clarify concepts related to energy conservation in simple harmonic oscillators.

clemente
Messages
2
Reaction score
0

Homework Statement



A particle moves along x-axis subject to a force toward the origin proportional to -kx. Find kinetic (K) and potential (P) energy as functions of time t, and show that total energy is contant.

Homework Equations



K = (1/2)m*v^2
P = (1/2)k*x^2
E = K+P

x = Asin(wt + [tex]\tau[/tex])

v = dx/dt = wA(cos(wt + [tex]\tau[/tex])

The Attempt at a Solution



K = (1/2)m*v^2 = (1/2)m*w^2A^2(cos^2(wt + [tex]\tau[/tex])

P = (1/2)k*x^2 = (1/2)k*A^2(sin^2(wt + [tex]\tau[/tex]))

But when I add these to get the total energy, the terms with t do not cancel, and so the total energy is not constant. I can only imagine then that I've done something wrong in the above, very basic steps. Any suggestions would be appreciated. Thanks.
 
Physics news on Phys.org
Another equation that comes in handy is w^2 = k/m. Rearranging this you get k = m*w^2 which can be substituted into the first equation, to get K = (1/2)m*v^2 = (1/2)k*A^2(cos^2(wt + [tex]\tau[/tex] )).

When adding K+P, the (1/2)k*A^2 (which is present in both terms) can now be taken as a common factor and using the trigonometric identity cos^2(x) + sin^2(x) = 1 shows the energy is constant.
 
Of course, that seems so obvious now! Thank you very much!
 

Similar threads

Sliding block hits and compresses a spring
  • · Replies 5 ·
Replies
5
Views
1K
Rotating simple harmonic oscillator
  • · Replies 11 ·
Replies
11
Views
2K
Oscillation of free surface of water in parallelepiped container
  • · Replies 13 ·
Replies
13
Views
2K
Position and acceleration in simple harmonic motion given velocity
  • · Replies 16 ·
Replies
16
Views
2K
How to set up this problem with driven torsional oscillator?
  • · Replies 5 ·
Replies
5
Views
1K
Estimating damped harmonic oscillator parameters from this plot of the oscillations
  • · Replies 9 ·
Replies
9
Views
2K
Potential/Kinetic Energy of Particles in Harmonic Oscillator
  • · Replies 2 ·
Replies
2
Views
2K
Energy of particle in simple harmonic motion
  • · Replies 13 ·
Replies
13
Views
1K
Two spring-coupled masses in an electric field (one of the masses is charged)
  • · Replies 1 ·
Replies
1
Views
1K
Simple Harmonic Oscillator behaviour when a potential term is added
  • · Replies 11 ·
Replies
11
Views
3K