A particle executing simple harmonic motion has kinetic and potential energies, both varying between the limits, zero and maximum. Here we will use the equations of a particle's displacement and velocity in SHM.
The velocity of a particle executing SHM, is a periodic function of time. It is zero at the extreme positions of displacement. Therefore, the kinetic energy (K) of such a particle, which is defined as
is also a periodic function of time, being zero when the displacement is maximum and maximum when the particle is at the mean position.Since the sign of v is immaterial in K, the period of K is T/2.The spring force F = –kx is a conservative force, with associated potential energy U = 1/2 K x^2.
Hence the potential energy of a particle executing simple harmonic motion is,
Thus the potential energy of a particle executing simple harmonic motion is also periodic, with period T/2, being zero at the mean position and maximum at the extreme displacements.Total Energy
The total mechanical energy of a harmonic oscillator is thus independent of time as expected for motion under any conservative force. The time and displacement dependence of the potential and kinetic energies of a linear simple harmonic oscillator are shown in figure.
In a linear harmonic oscillator, all energies are positive and peak twice during every period. For x = 0, the energy is all kinetic and for x = ± A it is all potential.In between these extreme positions, the potential energy increases at the expense of kinetic energy. The former stores its potential energy and the latter stores its kinetic energy.
SHM related topics
Time Period of Simple pendulum
What is periodic and Oscillatory Motion is ?
Displacement in Oscillatory motion
Simple Harmonic Motion
Velocity and acceleration of SHM
Topics of Heat and Thermodynamics
Heat engine
Internal Energy
Zeroth law of thermodynamics
Thermodynamics Introduction
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