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By the end of this section, you will be able to:
  • Describe the motion of damped harmonic motion
  • Write the equations of motion for damped harmonic oscillations
  • Describe the motion of driven, or forced, damped harmonic motion
  • Write the equations of motion for forced, damped harmonic motion

In the real world, oscillations seldom follow true SHM. Friction of some sort usually acts to dampen the motion so it dies away, or needs more force to continue. In this section, we examine some examples of damped harmonic motion and see how to modify the equations of motion to describe this more general case.

A guitar string stops oscillating a few seconds after being plucked. To keep swinging on a playground swing, you must keep pushing ( [link] ). Although we can often make friction and other nonconservative forces small or negligible, completely undamped motion is rare. In fact, we may even want to damp oscillations, such as with car shock absorbers.

A photo of a person on a swing
To counteract dampening forces, you need to keep pumping a swing. (credit: Bob Mical)

[link] shows a mass m attached to a spring with a force constant k . The mass is raised to a position A 0 , the initial amplitude, and then released. The mass oscillates around the equilibrium position in a fluid with viscosity but the amplitude decreases for each oscillation. For a system that has a small amount of damping, the period and frequency are constant and are nearly the same as for SHM, but the amplitude gradually decreases as shown. This occurs because the non-conservative damping force removes energy from the system, usually in the form of thermal energy.

A mass m is suspended from a vertical spring and immersed in a fluid that has viscosity eta. A graph of the damped oscillation shows the displacement x in meters on the vertical axis as a function of time in seconds on the horizontal axis. The range of x is from minus A sub zero to plus A sub zero. The time scale is from zero to 7 T, with tics at increments of T. The displacement is plus A sub zero at time zero and oscillates between positive maxima and negative minima, with each full cycle taking the same time T but the amplitude of the oscillations decreasing with time.
For a mass on a spring oscillating in a viscous fluid, the period remains constant, but the amplitudes of the oscillations decrease due to the damping caused by the fluid.

Consider the forces acting on the mass. Note that the only contribution of the weight is to change the equilibrium position, as discussed earlier in the chapter. Therefore, the net force is equal to the force of the spring and the damping force ( F D ) . If the magnitude of the velocity is small, meaning the mass oscillates slowly, the damping force is proportional to the velocity and acts against the direction of motion ( F D = b v ) . The net force on the mass is therefore

m a = b v k x .

Writing this as a differential equation in x , we obtain

m d 2 x d t 2 + b d x d t + k x = 0 .

To determine the solution to this equation, consider the plot of position versus time shown in [link] . The curve resembles a cosine curve oscillating in the envelope of an exponential function A 0 e α t where α = b 2 m . The solution is

x ( t ) = A 0 e b 2 m t cos ( ω t + ϕ ) .

It is left as an exercise to prove that this is, in fact, the solution. To prove that it is the right solution, take the first and second derivatives with respect to time and substitute them into [link] . It is found that [link] is the solution if

ω = k m ( b 2 m ) 2 .

Recall that the angular frequency of a mass undergoing SHM is equal to the square root of the force constant divided by the mass. This is often referred to as the natural angular frequency    , which is represented as

ω 0 = k m .
Practice Key Terms 4

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Source:  OpenStax, University physics volume 1. OpenStax CNX. Sep 19, 2016 Download for free at http://cnx.org/content/col12031/1.5
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