Difference between revisions of "User talk:Wheo001"
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− | We integrate this equation | + | We rearrange and integrate this equation with respect to <math>\xi</math> to give |
+ | <center><math>\frac{1}{3} \int H_{\xi\xi\xi} d\xi = \int 2V_0 H_{\xi} d\xi - 3\int H H_\xi d\xi</math></center> | ||
− | <center><math> \frac{1}{6}H_\xi^2=V_oH^2-\frac{1}{2}H^3+D_1H+D_2=f(H,V_0,D_1,D_2) </math></center> where D_1 and D_2 are constants of integration. | + | <center><math> \Longrightarrow |
+ | \frac{1}{3}H_{\xi\xi} = 2V_oH - \frac{3}{2}H^2 +D_1</math></center> | ||
+ | |||
+ | then multiply <math>H_\xi </math> to all terms and integrate again | ||
+ | |||
+ | |||
+ | |||
+ | <center><math>\Longrightarrow | ||
+ | \frac{1}{3}H_{\xi\xi} H_\xi = 2V_0HH_\xi - \frac{3H^2}{2}H_\xi + D_1H_\xi</math></center> | ||
+ | |||
+ | |||
+ | |||
+ | <center><math>\Longrightarrow | ||
+ | \frac{1}{3} \int H_{\xi\xi}H_\xi d\xi = 2V_o \int H H_\xi d\xi - \frac{3}{2} \int H^2H\xi d\xi + \int D_1 H_\xi d\xi</math></center> | ||
+ | |||
+ | |||
+ | <center><math>\Longrightarrow | ||
+ | \frac{1}{3} \cdot \frac{1}{2}H_\xi^2 = 2V_0 \frac{H^2}{2}-\frac{H^3}{2} +D_1H + D_2 </math></center> | ||
+ | |||
+ | |||
+ | |||
+ | <center><math> \Longrightarrow | ||
+ | \frac{1}{6}H_\xi^2=V_oH^2-\frac{1}{2}H^3+D_1H+D_2=f(H,V_0,D_1,D_2) </math></center> where <math>D_1</math> and <math>D_2</math> are constants of integration. | ||
==Standardization of KdV equation== | ==Standardization of KdV equation== | ||
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− | From the equation <math>f(H)=\frac{1}{6}H_\xi^2</math>, we require <math>f(H)>0 | + | From the equation <math>f(H)=\frac{1}{6}H_\xi^2</math>, we require <math>f(H)>0</math> |
We are only interested in solution for <math>H_2 < H < H_3</math> and we need <math>H_2 < H_3</math>. | We are only interested in solution for <math>H_2 < H < H_3</math> and we need <math>H_2 < H_3</math>. | ||
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where <math>X_i=\frac{H_i}{H}</math> | where <math>X_i=\frac{H_i}{H}</math> | ||
− | crest to be at <math>\xi=0 and X(0)=0</math> | + | crest to be at <math>\xi=0</math> and <math>X(0)=0</math> |
and a further variable Y via | and a further variable Y via | ||
− | <center><math> X=1+(X_2-1)sin^2(Y) </math></center> | + | <center><math> X = 1 +(X_2-1) \sin^2 (Y) </math></center> |
− | <center><math>Y_\xi^2=\frac{3}{4}H_3(1-X_1)\left\{ 1-\frac{(1-X_2)}{(1-X_1)}sin(Y)^2 \right\} | + | <center><math>Y_\xi^2=\frac{3}{4}H_3(1-X_1)\left\{ 1-\frac{(1-X_2)}{(1-X_1)}\sin(Y)^2 \right\} |
...(1)</math></center> | ...(1)</math></center> | ||
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so <math>Y(0)=0.</math> | so <math>Y(0)=0.</math> | ||
− | and <center><math>\frac{dY}{d\xi}=\sqrt{l(1-k^ | + | and <center><math>\frac{dY}{d\xi}=\sqrt{l(1-k^2\sin^2(Y))},</math></center> |
which is separable. | which is separable. | ||
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A simple quadrature of equation (1) subject to the condition (2) the gives us | A simple quadrature of equation (1) subject to the condition (2) the gives us | ||
− | <center><math>\int_{0}^\bar{Y} \frac{dS}{\sqrt{l(1-k^ | + | <center><math>\int_{0}^\bar{Y} \frac{dS}{\sqrt{l(1-k^2\sin^2(Y))}} = \int_{0}^\bar{Y} dS</math></center> |
− | Jacobi elliptic function <math> y= sn(x,k)</math> can be written in the form | + | Jacobi elliptic function <math>y= sn(x,k)</math> can be written in the form |
− | <center><math> x= \int_{0}^y \frac{dt}{\sqrt{1-t^2}\sqrt{1-k^2t^2}} | + | <center><math> x= \int_{0}^y \frac{dt}{\sqrt{1-t^2}\sqrt{1-k^2t^2}}</math></center> |
+ | for <math>0 < k^2 < 1 </math>, | ||
or equivalently | or equivalently | ||
− | <center><math> x=\int_{0}^{sin^{-1}y} \frac{dS}{\sqrt{1-k^ | + | <center><math> x=\int_{0}^{\sin^{-1}y} \frac{dS}{\sqrt{1-k^2\sin^2(s)}} </math></center> |
− | Now we can write Y with fixed values of x,k as | + | Now we can write Y with fixed values of <math>x</math>,<math>k</math> as |
− | <center><math> \bar{Y}=sin^{-1}(sn(\sqrt{l}\int_0^{\bar{Y}} d\xi,k)),</math></center> | + | <center><math> \bar{Y}=\sin^{-1}(\mathrm {sn} (\sqrt{l}\int_0^{\bar{Y}} d\xi,k)),</math></center> |
− | <center><math> sin(Y)=sn(\sqrt{l}\xi;k),</math></center> | + | <center><math> \sin(Y)=\mathrm {sn}(\sqrt{l}\xi;k),</math></center> |
and hence | and hence | ||
− | <center><math>X=1+(X_2-1)sn^2(\sqrt{l}\xi;k)</math></center> | + | <center><math>X=1+(X_2-1)\mathrm {sn}^2(\sqrt{l}\xi;k)</math></center> |
− | <math>cn(x;k)</math> is another Jacobi elliptic function with <math>cn^2+sn^2=1</math>, and waves are called "cnoidal waves". | + | <math>\mathrm {cn}(x;k)</math> is another Jacobi elliptic function with <math>\mathrm {cn}^2+\mathrm {sn}^2=1</math>, and waves are called "cnoidal waves". |
Using the result <math>cn^2+sn^2=1</math>, our final result can be expressed in the form | Using the result <math>cn^2+sn^2=1</math>, our final result can be expressed in the form | ||
− | <center><math>H=H_2+(H_3-H_2)cn^2\left\{ \left[ \frac{3}{4}(H_3-H_1) \right]^{\frac{1}{2}}\xi;k \right\} </math></center> | + | <center><math>H=H_2+(H_3-H_2)\mathrm {cn}^2\left\{ \left[ \frac{3}{4}(H_3-H_1) \right]^{\frac{1}{2}}\xi;k \right\} </math></center> |
Latest revision as of 07:19, 17 October 2008
Travelling Wave Solutions of the KdV Equation
The KdV equation has two qualitatively different types of permanent form travelling wave solution. These are referred to as cnoidal waves and solitary waves.
KdV equation in [math]\displaystyle{ (z,\tau) }[/math] space
Assume we have wave travelling with speed [math]\displaystyle{ V_0 }[/math] without change of form,
and substitute into KdV equation then we obtain
where [math]\displaystyle{ \xi=z-V_0\tau }[/math] is the travelling wave coordinate.
We rearrange and integrate this equation with respect to [math]\displaystyle{ \xi }[/math] to give
then multiply [math]\displaystyle{ H_\xi }[/math] to all terms and integrate again
where [math]\displaystyle{ D_1 }[/math] and [math]\displaystyle{ D_2 }[/math] are constants of integration.
Standardization of KdV equation
We define [math]\displaystyle{ f(H)= V_oH^2-\frac{1}{2}H^3+D_1H+D2 }[/math], so [math]\displaystyle{ f(H)=\frac{1}{6}H_\xi^2 }[/math]
It turns out that we require 3 real roots to obtain periodic solutions. Let roots be [math]\displaystyle{ H_1 \leq H_2 \leq H_3 }[/math].
We can imagine the graph of cubic function which has 3 real roots and we can now write a function
From the equation [math]\displaystyle{ f(H)=\frac{1}{6}H_\xi^2 }[/math], we require [math]\displaystyle{ f(H)\gt 0 }[/math]
We are only interested in solution for [math]\displaystyle{ H_2 \lt H \lt H_3 }[/math] and we need [math]\displaystyle{ H_2 \lt H_3 }[/math].
and now solve equation in terms of the roots [math]\displaystyle{ H_i, }[/math]
We define [math]\displaystyle{ X=\frac{H}{H_3} }[/math], and obtain
where [math]\displaystyle{ X_i=\frac{H_i}{H} }[/math]
crest to be at [math]\displaystyle{ \xi=0 }[/math] and [math]\displaystyle{ X(0)=0 }[/math]
and a further variable Y via
so [math]\displaystyle{ Y(0)=0. }[/math]
and
which is separable.
In order to get this into a completely standard form we define
Clearly, [math]\displaystyle{ 0 \leq k^2 \leq 1 }[/math] and [math]\displaystyle{ l\gt 0. }[/math]
Solution of the KdV equation
A simple quadrature of equation (1) subject to the condition (2) the gives us
Jacobi elliptic function [math]\displaystyle{ y= sn(x,k) }[/math] can be written in the form
for [math]\displaystyle{ 0 \lt k^2 \lt 1 }[/math],
or equivalently
Now we can write Y with fixed values of [math]\displaystyle{ x }[/math],[math]\displaystyle{ k }[/math] as
and hence
[math]\displaystyle{ \mathrm {cn}(x;k) }[/math] is another Jacobi elliptic function with [math]\displaystyle{ \mathrm {cn}^2+\mathrm {sn}^2=1 }[/math], and waves are called "cnoidal waves".
Using the result [math]\displaystyle{ cn^2+sn^2=1 }[/math], our final result can be expressed in the form