Character sum: Difference between revisions

Revision as of 13:57, 8 January 2014

The Duffing equation, named after Georg Duffing, is a non-linear second-order differential equation used to model certain damped and driven oscillators. The equation is given by

{\ddot {x}}+\delta {\dot {x}}+\alpha x+\beta x^{3}=\gamma \cos(\omega t)\,

where the (unknown) function x=x(t) is the displacement at time t, ${\dot {x}}$ is the first derivative of x with respect to time, i.e. velocity, and ${\ddot {x}}$ is the second time-derivative of x, i.e. acceleration. The numbers $\delta$ , $\alpha$ , $\beta$ , $\gamma$ and $\omega$ are given constants.

The equation describes the motion of a damped oscillator with a more complicated potential than in simple harmonic motion (which corresponds to the case β=δ=0); in physical terms, it models, for example, a spring pendulum whose spring's stiffness does not exactly obey Hooke's law.

The Duffing equation is an example of a dynamical system that exhibits chaotic behavior. Moreover the Duffing system presents in the frequency response the jump resonance phenomenon that is a sort of frequency hysteresis behaviour.

Parameters

$\delta$ controls the size of the damping.
$\alpha$ controls the size of the stiffness.
$\beta$ controls the amount of non-linearity in the restoring force. If $\beta =0$ , the Duffing equation describes a damped and driven simple harmonic oscillator.
$\gamma$ controls the amplitude of the periodic driving force. If $\gamma =0$ we have a system without driving force.
$\omega$ controls the frequency of the periodic driving force.

Methods of solution

In general, the Duffing equation does not admit an exact symbolic solution. However, many approximate methods work well:

Expansion in a Fourier series will provide an equation of motion to arbitrary precision.
The $x^{3}$ term, also called the Duffing term, can be approximated as small and the system treated as a perturbed simple harmonic oscillator.
The Frobenius method yields a complicated but workable solution.
Any of the various numeric methods such as Euler's method and Runge-Kutta can be used.

In the special case of the undamped ( $\delta =0$ ) and undriven ( $\gamma =0$ ) Duffing equation, an exact solution can be obtained using Jacobi's elliptic functions.

References

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External links

Template:Chaos theory

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+{{no footnotes|date=June 2013}}
+[[File:Forced Duffing equation Poincaré section.png|thumb|A [[Poincaré section]] of the forced Duffing equation suggesting chaotic behaviour]]
+The '''Duffing equation''', named after [[Georg Duffing]], is a [[non-linear]] second-order [[differential equation]] used to model certain [[damping|damped]] and driven [[oscillator]]s. The equation is given by
+:<math>\ddot{x} + \delta \dot{x} + \alpha x + \beta x^3 = \gamma \cos (\omega t)\,</math>
+where the (unknown) function ''x''=''x''(''t'') is the displacement at time ''t'', <math>\dot{x}</math> is the first [[derivative]] of ''x'' with respect to time, i.e. [[velocity]], and <math>\ddot{x}</math> is the second time-derivative of ''x'', i.e. [[acceleration]]. The numbers <math>\delta</math>, <math>\alpha</math>, <math>\beta</math>, <math>\gamma</math> and <math>\omega</math> are given constants.
+The equation describes the motion of a damped oscillator with a more complicated [[potential]] than in [[simple harmonic motion]] (which corresponds to the case β=δ=0); in physical terms, it models, for example, a [[spring pendulum]] whose spring's [[stiffness]] does not exactly obey [[Hooke's law]].
+The Duffing equation is an example of a dynamical system that exhibits [[chaos theory|chaotic behavior]].
+Moreover the Duffing system presents in the frequency response the jump resonance phenomenon that is a sort of frequency hysteresis behaviour.
+==Parameters==
+* <math>\delta</math> controls the size of the [[damping]].
+* <math>\alpha</math> controls the size of the [[stiffness]].
+* <math>\beta</math> controls the amount of non-linearity in the restoring force. If <math>\beta=0</math>, the Duffing equation describes a damped and driven simple harmonic oscillator.
+* <math>\gamma</math> controls the [[amplitude]] of the periodic driving force. If <math>\gamma=0</math> we have a system without driving force.
+* <math>\omega</math> controls the [[frequency]] of the periodic driving force.
+==Methods of solution==
+[[File:Duffing oscillator limit cycle.gif|thumb|right|300px|Duffing oscillator limit cycle  γ>0]]
+[[File:Duffing oscillator limit cycle phase animation.gif|thumb|right|300px|Duffing oscillator limit cycle phase animation  γ>0]]
+[[File:Duffing oscillator chaos.gif|thumb|300px|right|Duffing oscillator chaos oscillation γ<0]]
+[[File:Duffing oscillator attractors animation.gif|thumb|right|300px|Duffing oscillator attractors animation γ<0]]
+In general, the Duffing equation does not admit an exact symbolic solution. However, many approximate methods work well:
+* Expansion in a [[Fourier series]] will provide an equation of motion to arbitrary precision.
+* The <math>x^3</math> term, also called the ''Duffing term'', can be approximated as small and the system treated as a [[perturbation theory|perturbed]] simple harmonic oscillator.
+* The [[Frobenius method]] yields a complicated but workable solution.
+* Any of the various [[numerical analysis|numeric methods]] such as [[Euler's method]] and [[Runge-Kutta]] can be used.
+In the special case of the undamped (<math>\delta = 0</math>) and undriven (<math>\gamma = 0</math>) Duffing equation, an exact solution can be obtained using [[Jacobi's elliptic functions]].
+==References==
+{{reflist}}
+== External links ==
+* [http://scholarpedia.org/article/Duffing_oscillator Duffing oscillator on Scholarpedia]
+* [http://mathworld.wolfram.com/DuffingDifferentialEquation.html MathWorld page]
+{{Chaos theory}}
+[[Category:Ordinary differential equations]]
+{{mathapplied-stub}}

Character sum: Difference between revisions

Revision as of 13:57, 8 January 2014

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Parameters

Methods of solution

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Character sum: Difference between revisions

Revision as of 13:57, 8 January 2014

Parameters

Methods of solution

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