KdV equation: Difference between revisions

Latest revision as of 14:12, 24 July 2020

This is the Korteweg de Vries equation for a quantity $A(x,t)$ in physical form
$A_{t}=-cA_{x}+\alpha AA_{x}+\beta A_{xxx}\,$
where subscripts denote partial derivatives.

The parameter c denotes the linear advective wave speed, the parameter $\alpha$ denotes the nonlinear effects while the parameter $\beta$ denotes the dispersive effect. In practice these parameters depend on the physical situation considered.

To understand the meaning of the nonlinear and dispersive terms consider them one at a time.

The nonlinear term: $A_{t}=-(c-\alpha A)A_{x}.\,$ $A_{t}=-(c-\alpha A)A_{x}.\,$
- You can see that if $A>0$ and $\alpha$ is negative then larger waves have faster propagation speeds.
The Fourier transform of the dispersive term: ${\bar {A}}_{t}=-ik(c-\beta k^{2}){\bar {A}}.$ ${\bar {A}}_{t}=-ik(c-\beta k^{2}){\bar {A}}.$ (where $k$ $k$ is the wavenumber)
- Thus when $\beta$ is positive shorter waves (with larger k) propagate slower.

The Wave Envelope page uses the KdV equation to illustrate the difference between group velocity and phase speed via wave envelopes.

@@ Line 7: / Line 7: @@
 The parameter c denotes the linear advective wave speed, the parameter <math>\alpha</math> denotes the nonlinear effects while the parameter <math>\beta</math> denotes the dispersive effect.  In practice these parameters depend on the physical situation considered.
-To understand the meaning of the nonlinear and dispersive terms consider them one at a time.  First the nonlinear term
+To understand the meaning of the nonlinear and dispersive terms consider them one at a time.
-<br>
+* The nonlinear term: <math>A_t = -(c-\alpha A) A_x.\, </math>
-<math>A_t = -(c-\alpha A) A_x.\, </math>
+** You can see that if <math>A>0</math> and <math>\alpha</math> is negative then larger waves have faster propagation speeds.
-<br>
+* The Fourier transform of the dispersive term: <math>\bar{A}_t = -ik(c-\beta k^2) \bar{A}. </math> (where <math>k</math> is the wavenumber)
-You can see that if <math>A>0</math> and <math>\alpha</math> is negative then larger waves have faster propagation speeds.  For the dispersive term we need to Fourier transform to see that
+** Thus when <math>\beta</math> is positive shorter waves (with larger k) propagate slower.
-<br>
-<math>\bar{A}_t = -ik(c-\beta k^2) \bar{A}. </math>
+The [[Wave Envelope]] page uses the KdV equation to illustrate the difference between group velocity and phase speed via wave envelopes.
-<br>
-where <math>k</math> is the wavenumber.  Thus when <math>\beta</math> is positive shorter waves (with larger k) propagate slower.

KdV equation: Difference between revisions

Latest revision as of 14:12, 24 July 2020

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