madorangepand
Aug25-08, 09:53 AM
A space shuttle is in orbit travelling with velocity v with respect to the Earth, along the x direction. The crew launch a satellite forward with velocity u in their own rest frame. The speed of the satellite relative to the Earth is w. A beacon on the satellite emits photons of wavelength \lambda in all directions in the satellite rest frame.
i) Define the z axis as the axis joining the photon to the Earth, i.e perpendicular to its velocity in the rest frame of the satellite. Give an expression in terms of w and \lambda0 for
1. the wavelength \lambda1, of a photon emitted along the x axis
2. the wavelength \lambda2, of a photon emitted along the z axis
as seen by an observer stationary with respect to the Earth.
ii)A realistic value for w is v=30m/s. comment on the values of \lambda1 and \lambda2 in this case, and on the implications of your answer for GPS satellites which emit a signal at a particular frequency.
iii)Write down the equation for time dilation, and comment on the effect on a clock on the satellite which has to stay in time with one on the Earth.
iv)Wrtie down the four-vector momentum, p, of a photon which is emitted along the x direction, in terms of \lambda0
Give a matrix equation for the four-vector momentum, p', of this photon in the rest frame of the Earth, in terms of u, v and p.
Use this equation to show that the velocity, w, of the satellite in the rest frame of the Earth is given by
w=\frac{u+v}{1+\frac{uv}{c^2}}
ii) and iii) I can do with ease (they are the easy bits after all)
I can't even seem to start parts i) or iv)
i) Define the z axis as the axis joining the photon to the Earth, i.e perpendicular to its velocity in the rest frame of the satellite. Give an expression in terms of w and \lambda0 for
1. the wavelength \lambda1, of a photon emitted along the x axis
2. the wavelength \lambda2, of a photon emitted along the z axis
as seen by an observer stationary with respect to the Earth.
ii)A realistic value for w is v=30m/s. comment on the values of \lambda1 and \lambda2 in this case, and on the implications of your answer for GPS satellites which emit a signal at a particular frequency.
iii)Write down the equation for time dilation, and comment on the effect on a clock on the satellite which has to stay in time with one on the Earth.
iv)Wrtie down the four-vector momentum, p, of a photon which is emitted along the x direction, in terms of \lambda0
Give a matrix equation for the four-vector momentum, p', of this photon in the rest frame of the Earth, in terms of u, v and p.
Use this equation to show that the velocity, w, of the satellite in the rest frame of the Earth is given by
w=\frac{u+v}{1+\frac{uv}{c^2}}
ii) and iii) I can do with ease (they are the easy bits after all)
I can't even seem to start parts i) or iv)