Free wave equation: Difference between revisions
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The '''free wave equation''' on <math>R^{1+d}</math> is given by | The '''free wave equation''' on <math>{\mathbb R}^{1+d}</math> is given by | ||
<center><math>\Box f = 0</math></center> | <center><math>\Box f = 0</math></center> | ||
where ''f'' is a scalar or vector field on [[Minkowski space]] <math>R^{1+d}</math>. | where ''f'' is a scalar or vector field on [[Minkowski space]] <math>{\mathbb R}^{1+d}</math>. | ||
In coordinates, this becomes | In coordinates, this becomes | ||
<center><math>- \partial_{tt} f + \Delta f = 0.</math></center> | <center><math>- \partial_{tt} f + \Delta f = 0.</math></center> | ||
Line 7: | Line 7: | ||
One can add a mass term to create the [[Klein-Gordon equation]]. | One can add a mass term to create the [[Klein-Gordon equation]]. | ||
== Exact solutions == | |||
Being this a linear equation one can always write down a solution using Fourier series or transform. These solutions represent superpositions of traveling waves. | |||
=== Solution in <math>{\mathbb R}^{1+1}</math> === | |||
In this case one can write down the solution as | |||
<center><math>\, f(x,t)=g_1(x-t)+g_2(x+t)\!</math></center> | |||
being <math>g_1,\ g_2</math> two arbitrary functions and <math>\, x\in {\mathbb R}\!</math>. This gives a complete solution to the Cauchy problem that can be cast as follows | |||
<center><math>\, f=f_0(x),\ \partial_tf=f_1(x)\!</math></center> | |||
for <math>\, t=0\!</math>, so that | |||
<center><math>f(x,t)=\frac{1}{2}[f_0(x+t)+f_0(x-t)]+\frac{1}{2}[F_1(x+t)+F_1(x-t)]</math></center> | |||
being <math>\, F_1\!</math> an arbitrarily chosen primitive of <math>\, f_1\!</math>. | |||
=== Solution in <math>{\mathbb R}^{1+d}</math> === | |||
Solution of the Cauchy problem in <math>{\mathbb R}^{1+d}</math> can be given as follows [[You1966]]. We have | |||
<center><math>\, f=f_0(x),\ \partial_tf=0\!</math></center> | |||
for <math>\, t=0\!</math>, but now <math>\, x\in {\mathbb R}^d\!</math>. One can write the solution as | |||
<center><math>f(x,t)=\frac{t\sqrt{\pi}}{\Gamma(d/2)}\left(\frac{\partial}{\partial t^2}\right)^{(d-1)/2}[t^{d-2}\phi(x,t)]</math></center> | |||
when d is odd and | |||
<center><math>f(x,t)=\frac{2t}{\Gamma(d/2)}\left(\frac{\partial}{\partial t^2}\right)^{d/2}\int_0^t t_1^{d-2}\phi(x,t_1)\frac{t_1dt_1}{\sqrt{t^2-t_1^2}}</math></center> | |||
when d is even, being | |||
<center><math>\, \phi(x,t)=\frac{1}{\Omega_d}\int_{\Sigma(t)} f_0(x')d\Omega_d\!</math></center> | |||
on the surface of the d-sphere centered at x and with radius t. | |||
[[Category:Wave]] | [[Category:Wave]] | ||
[[Category:Equations]] | [[Category:Equations]] |
Latest revision as of 16:00, 1 July 2018
The free wave equation on is given by
where f is a scalar or vector field on Minkowski space . In coordinates, this becomes
It is the prototype for many nonlinear wave equations.
One can add a mass term to create the Klein-Gordon equation.
Exact solutions
Being this a linear equation one can always write down a solution using Fourier series or transform. These solutions represent superpositions of traveling waves.
Solution in
In this case one can write down the solution as
being two arbitrary functions and . This gives a complete solution to the Cauchy problem that can be cast as follows
for , so that
being an arbitrarily chosen primitive of .
Solution in
Solution of the Cauchy problem in can be given as follows You1966. We have
for , but now . One can write the solution as
when d is odd and
when d is even, being
on the surface of the d-sphere centered at x and with radius t.