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Damped Simple Harmonic Motion


Adding a damping force proportional to x^. to the equation of simple harmonic motion, the first derivative of x with respect to time, the equation of motion for damped simple harmonic motion is

 x^..+betax^.+omega_0^2x=0,
(1)

where beta is the damping constant. This equation arises, for example, in the analysis of the flow of current in an electronic CLR circuit, (which contains a capacitor, an inductor, and a resistor). The curve produced by two damped harmonic oscillators at right angles to each other is called a harmonograph, and simplifies to a Lissajous curve if beta_1=beta_2=0.

The damped harmonic oscillator can be solved by looking for trial solutions of the form x=e^(rt). Plugging this into (1) gives

 (r^2+betar+omega_0^2)e^(rt)=0
(2)
 r^2+betar+omega_0^2=0.
(3)

This is a quadratic equation with solutions

 r=1/2(-beta+/-sqrt(beta^2-4omega_0^2)).
(4)

There are therefore three solution regimes depending on the sign of the quantity inside the square root,

 D=beta^2-4omega_0^2.
(5)

The three regimes are summarized in the following table.

If a periodic (sinusoidal) forcing term is added at angular frequency omega, the same three solution regimes are again obtained. Surprisingly, the resulting motion is still periodic (after an initial transient response, corresponding to the solution to the unforced case, has died out), but it has an amplitude different from the forcing amplitude.

The particular solution x^*(t) to the forced second-order nonhomogeneous ordinary differential equation

 x^..+p(t)x^.+q(t)x=Ccos(omegat)
(6)

due to forcing can be found using variation of parameters to be given by the equation

 x^*(t)=-x_1(t)int(x_2(t)g(t))/(W(t))dt+x_2(t)int(x_1(t)g(t))/(W(t))dt,
(7)

where x_1(t) and x_2(t) are the homogeneous solutions to the unforced equation

 x^..+p(t)x^.+q(t)x=0
(8)

and W(t) is the Wronskian of these two functions. Once the sinusoidal case of forcing is solved, it can then be generalized to any periodic function by expressing the periodic function in a Fourier series.


See also

Critically Damped Simple Harmonic Motion, Harmonograph, Lissajous Curve, Overdamped Simple Harmonic Motion, Simple Harmonic Motion, Underdamped Simple Harmonic Motion, Variation of Parameters

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References

Papoulis, A. "Motion of a Harmonically Bound Particle." §15-2 in Probability, Random Variables, and Stochastic Processes, 2nd ed. New York: McGraw-Hill, pp. 524-528, 1984.

Referenced on Wolfram|Alpha

Damped Simple Harmonic Motion

Cite this as:

Weisstein, Eric W. "Damped Simple Harmonic Motion." From MathWorld--A Wolfram Web Resource. https://mathworld.wolfram.com/DampedSimpleHarmonicMotion.html

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