Partial Differential Equation in Special Relativity

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Nerrad
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Homework Statement


(a) Light waves satisfy the wave equation ##u_{tt}-c^2u_{xx}## where ##c## is the speed of light.
Consider change of coordinates $$x'=x-Vt$$ $$t'=t$$
where V is a constant. Use the chain rule to show that ##u_x=u_{x'}## and ##u_{tt}=-Vu_{x'}+u_{t'}##
Find ##u_{xx},u_{tt},## and hence ##u_{tt}-c^2u_{xx}##, in terms of derivatives with respect to ##x'## and ##t'##.
Deduce that if ##u## satisfies the wave equation in ##x,t## coordinates, then it does not satisfy the same equation in the ##x',t'## coordinates.

The Attempt at a Solution


So I've worked out that $$u_{xx}=u_{x'x'}$$ and $$u_{tt}=u_{t't'}+v^2(u_{x'x'})-2v(u_{x'xt})$$ so technically ##u_{tt}-c^2u_{xx}## expressed in terms of derivatives with respect to ##x'## and ##t'## would just be $$u_{t't'}+v^2(u_{x'x'})-2v(u_{x'xt})-c^2(u_{x'x'})=0$$ right?
But how do I do the bit where question says "Deduce that if ##u## satisfies the wave equation in ##x,t## coordinates, then it does not satisfy the same equation in the ##x',t'## coordinates." I don't know where to start with this?Would this be done conceptually or mathematically?
 
on Phys.org
kuruman said:
Start with the wave equation.
Can you give a little bit more hints than that please? Thanks
 
I give up. Can you guide me through this. Please. Thanks
 
Last edited:
Is it simply due to the fact that ##u_{xx}-c^2u_{tt} \neq u_{x'x'}-c^2u_{t't'} ##, so that if ##u## satisfies the wave equation in ##x##,##t## coordinates, then it does not satisfy the same equation in the ##x'##,##t'## coordinates? Or do I deduce it mathematically?